Herbicide resistant plants

ABSTRACT

The present invention relates to the production of a non-transgenic plant resistant or tolerant to a herbicide of the phosphonomethylglycine family, e.g., glyphosate. The present invention also relates to the use of a recombinagenic Oligonucleobase to make a desired mutation in the chromosomal or episomal sequences of a plant in the gene encoding for 5-enol pyruvylshikimate-3-phosphate synthase (EPSPS). The mutated protein, which substantially maintains the catalytic activity of the wild-type protein, allows for increased resistance or tolerance of the plant to a herbicide of the phosphonomethylglycine family, and allows for the substantially normal growth or development of the plant, its organs, tissues or cells as compared to the wild-type plant irrespective of the presence or absence of the herbicide. The present invention also relates to a non-transgenic plant cell in which the EPSPS gene has been mutated, a non-transgenic plant regenerated therefrom, as well as a plant resulting from a cross using a regenerated non-transgenic plant having a mutated EPSPS gene.

[0001] The present application claims priority to U.S. Provisional Application No. 60/158,027, filed on Oct. 7, 1999 and to U.S. Provisional Application No. 60/173,564, filed Dec. 30, 1999, the disclosures of each of which are incorporated by reference herein in their entirety.

1. FIELD OF THE INVENTION

[0002] The present invention relates to the production of a non-transgenic plant resistant or tolerant to a herbicide of the phosphonomethylglycine family, e.g., glyphosate. The present invention also relates to the use of a recombinagenic oligonucleobase to make a desired mutation in the chromosomal or episomal sequences of a plant in the gene encoding for 5-enol pyruvylshikimate-3-phosphate synthase (EPSPS). The mutated protein, which substantially maintains the catalytic activity of the wild-type protein, allows for increased resistance or tolerance of the plant to a herbicide of the phosphonomethylglycine family, and allows for the substantially normal growth or development of the plant, its organs, tissues or cells as compared to the wild-type plant irrespective of the presence or absence of the herbicide. The present invention also relates to a non-transgenic plant cell in which the EPSPS gene has been mutated, a non-transgenic plant regenerated therefrom, as well as a plant resulting from a cross using a regenerated non-transgenic plant having a mutated EPSPS gene.

2. BACKGROUND TO THE INVENTION

[0003] 2.1 Phosphonomethylglycine Herbicides

[0004] Herbicide-tolerant plants may reduce the need for tillage to control weeds thereby effectively reducing soil erosion. One herbicide which is the subject of much investigation in this regard is N-phosphonomethylglycine, commonly referred to as glyphosate. Glyphosate inhibits the shikimic acid pathway which leads to the biosynthesis of aromatic compounds including amino acids, hormones and vitamins. Specifically, glyphosate curbs the conversion of phosphoenolpyruvic acid (PEP) and 3-phosphoshikimic acid to 5-enolpyruvyl-3-phosphoshikimic acid by inhibiting the enzyme 5-enolpyruvylshikimate-3-phosphate synthase (hereinafter referred to as EPSP synthase or EPSPS). For purposes of the present invention, the term “glyphosate” includes any herbicidally effective form of N-phosphonomethylglycine (including any salt thereof), other forms which result in the production of the glyphosate anion in plants and any other herbicides of the phosphonomethlyglycine family.

Herbicide Resistant Plants

[0005] The present invention relates to recombinant DNA technology, and in particular to the production of transgenic plants which exhibit substantial resistance or substantial tolerance to herbicides when compared with non transgenic like plants. The invention also relates, inter alia, to the nucleotide sequences (and expression products thereof), which are used in the production of, or are produced by, the said transgenic plants.

[0006] Plants which are substantially “tolerant” to a herbicide when they are subjected to it provide a dose/response curve which is shifted to the right when compared with that provided by similarly subjected non tolerant like plants. Such dose/response curves have “dose” plotted on the x-axis and “percentage kill”, “herbicidal effect” etc. plotted on the y-axis. Tolerant plants will typically require at least twice as much herbicide as non tolerant like plants in order to produce a given herbicidal effect. Plants which are substantially “resistant” to the herbicide exhibit few, if any, necrotic, lytic, chlorotic or other lesions when subjected to the herbicide at concentrations and rates which are typically employed by the agricultural community to kill weeds in the field in which crops are to be grown for commercial purposes.

[0007] It is particularly preferred that the plants are substantially resistant or substantially tolerant to herbicides (hereinafter “glyphosate”) which have 5-enol pyruvyl shikimate phosphate synthetase (hereinafter “EPSPS”) as their site of action, of which N-phosphonomethylglycine (and its various salts) is the pre-eminent example.

[0008] The herbicide may be applied either pre- or post emergence in accordance with usual techniques for herbicide application to fields comprising crops which have been rendered resistant to the herbicide. The present invention provides, inter alia, nucleotide sequences useful in the production of such herbicide tolerant or resistant plants.

[0009] According to the present invention there is provided a glyphosate resistant EPSPS enzyme wherein in comparison with the wild type EPSPS the protein sequence is modified in that a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPL in the wild type enzyme such that the modified sequence reads GNAGIAMRSL, wherein the enzyme does not comprise the sequence K(A/V)AKRAVVVGCGGKFPVE, characterised in that the enzyme is stable and possesses at least one of the following sequence motifs (i) to (viii) in which X is any amino acid and Z, Z₁ and Z₂ are any amino acid other than those specified:

[0010] (i) ALLMZAPLA, wherein Z is not S or T;

[0011] (ii) EIEIZDKL, wherein Z is not V;

[0012] (iii) FG(V/I)(K/S)ZEH, wherein Z is not V;

[0013] (iv) AL(K/R)ZLGL, wherein Z is not R;

[0014] (v) GLXVEZ₁DXZ₂XXXA(I/V)V, wherein Z₁ is not T and/or Z₂ is not E;

[0015] (vi) ITPPZ₁K(L/V)(K/N)Z₂, wherein Z₁ is not K and/or Z₂ is not T;

[0016] (vii) TIZ(D/N)PGCT, wherein Z is not N or L;

[0017] (viii) (D/N)YFXVLXZXX(K/R)H, wherein Z is not R.

[0018] A preferred embodiment of the enzyme comprises at least two of the motifs (i), (ii), (iii), (v) and (vi). In specific embodiments of the present inventive enzyme in motif (i) Z is A; in motif (ii) Z is I; in motif (iii) Z is A; in motif (iv) Z is K, T or A; in motif (v) Z, is R or A or less preferably D or E and Z₂ is preferably V or A or less preferably T; in sequence motif (vi) Z₁ is E or A and Z₂ is P, I or V; in motif (vii) Z is R or K; and in motif (viii) Z is T or S or less preferably Q. Particularly preferred embodiments of the said enzyme comprise one or more sequences selected from the group consiting of: (i) (IIV)VEGCGG(I/L/Q)FP(V/A/T)(S/G) (ii) (I/V)VVGCGG(I/L/Q)FP(V/A/T)E; (iii) (I/V)VVGCGG(I/L/Q)FP(V/A/T)(S/G); (iv) (I/V)VVGCGGKFP(V/A/T)(S/G); (v) (I/V)VEGCGGKFP(V/A/T)E; (vi) (I/V)VEGCGG(I/L/Q)FP(V/A/T)E; (vii) (I/V)VEGCGGKFP(V/A/T)(S/G).

[0019] The present invention also comprises an isolated polynucleotide comprising a region which encodes the present inventive enzyme, particular such polynucleotides comprising, for example, a sequence depicted in SEQ ID Nos. 4 or 5, or a sequence obtained by hybridising an intron located in the SEQ ID 4 or 5 sequences with polynucleotides comprised in plant genomic libraries. The invention also includes an isolated polynucleotide comprising a region encoding a chloroplast transit peptide and a glyphosate resistant dicotyledenous 5-enolpyruvylshiikimate phosphate synthase (EPSPS) 3′ of the peptide, the said region being under expression control of a plant operable promoter, with the provisos that the said promoter is not heterologous with respect to the said region, and the chloroplast transit peptide is not heterologous with respect to the said synthase.

[0020] By “heterologous” is meant from a different source, and correspondingly “non-heterologous” means derived from the same source—but at a gene rather than organism or tissue level. For example the CaMV35S promoter is clearly heterologous with respect to a petunia EPSPS coding sequence insofar as the promoter is derived from a virus and the sequence—the expression of which it controls—from a plant. The term “heterologous” according to the present invention has a still narrower meaning, however. For example “heterologous” as it relates to the present invention means that the petunia EPSPS coding sequence is “heterologous” with respect to, for example, a promoter also derived from petunia—other than that which controls expression of the EPSPS gene. In this sense the petunia promoter derived from the petunia EPSPS gene then used to control expression of an EPSPS coding sequence likewise-derived from petunia is “non-heterologous” with respect to the said coding sequence. “Non-heterologous” does not mean, however, that the promoter and coding sequence must necessarily have been obtained from one and the same (original or progenitor) polynucleotide. Likewise with respect to transit peptides. For example, a rubisco chloroplast transit peptide derived from sunflower is “heterologous” with respect to the coding sequence of an EPSPS gene likewise derived from sunflower (the same plant, tissue or cell). A rubisco transit peptide encoding sequence derived from sunflower is “non-heterologous” with respect to a rubisco enzyme encoding-sequence also derived from sunflower even if the origins of both sequences are different polynucleotides which may have been present in different cells, tissues or sunflower plants.

[0021] Most particularly preferred forms of the said polynucleotide include a construct which comprises the following components in the 5′ to 3′ direction of transcription: either (1):

[0022] (i) At least one transcriptional enhancer being that enhancing region which is upstream from the transcriptional start of the sequence from which the enhancer is obtained and which enhancerper se does not function as a promoter either in the sequence in which it is endogenously comprised or when present heterologously as part of a construct;

[0023] (ii) The promoter from the soybean EPSPS gene;

[0024] (iii) The soybean genomic sequence which encodes the soybean EPSPS chloroplast transit peptide;

[0025] (iv) The genomic sequence which encodes the soybean EPSPS;

[0026] (v) A transcriptional terminator;

[0027] wherein the soybean EPSPS coding sequence is modified in comparison with a wild type sequence in that a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPLTAAV in the wild type enzyme such that modified sequence reads GNAGIAMRSLTAAV; or (2)

[0028] (i) At least one transcriptional enhancer being that enhancing region which is upstream from the transcriptional start of the sequence from which the enhancer is obtained and which enhancer per se does not function as a promoter either in the sequence in which it is endogenously comprised or when present heterologously as part of a construct;

[0029] (ii) The promoter from the Brasicca napus EPSPS gene;

[0030] (iii) The Brasicca napus genomic sequence which encodes the Brasicca napus EPSPS chloroplast transit peptide;

[0031] (iv) The genomic sequence which encodes the Brasicca napus EPSPS;

[0032] (v) A transcriptional terminator;

[0033] wherein the Brasicca napus EPSPS coding sequence is modified in comparison with a wild type sequence in that a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPLTAAV in the wild type enzyme such that the modified sequence reads GNAGIAMRSLTAAV.

[0034] The present inventive polynucleotide, particularly the two disclosed in the immediately preceding paragraphs, may further comprise a sequence which encodes a chloroplast transit peptide/phosphoenolpyruvate synthase (CTP/PPS) or a chloroplast transit peptide/pyruvate orthophosphate di-kinase (CTP/PPDK), which sequence is under expression control of a plant operable promoter. It is particularly preferred that the PPDK protein sequence is directed to the chloroplast in planta via its autologous transit peptide, and accordingly the polynucleotide of the immediately preceding sentence encodes such a non-heterologous combination. The PPDK encoding sequence can be derived from either a monocot or a dicot and the protein thus encoded is optionally not cold-labile. By “not cold labile” is meant that the enzyme retains at least 50% of its activity when incubated at 0 degrees Celsius for 5 minutes under experimental conditions similar to thosereferred to in. Usami et-al (1995) Plant Mol. Biol., 27, 969-980. Such a ‘cold stable’ enzyme is at least two-fold more stable-than the like enzyme isolated from F. bidentis. The PPS or PPDK enzymes provide for elevated levels of PEP in the chloroplast which is the site of action of glyphosate and which contains the EPSPS enzyme.

[0035] The enhancing region of the polynucleotide preferably constitutes a sequence the 3′ end of which is at least 40 nucleotides upstream of the closest transcriptional start of the sequence from which the enhancer is obtained. In a furter embodiment of the polynucleotide, the enhancing region constitutes a region the 3′ end of which is at least 60 nucleotides upstream of the said closest start, and in a still further embodiment of the polynucleotide the said enhancing region constitutes a sequence the 3′ of which is at least 10 nucleotides upstream from the first nucleotide of the TATA consensus of the sequence from which the enhancer is obtained.

[0036] The polynucleotide according to the invention may comprise two or more transcriptional enhancers, which in a particular embodiment of the polynucleotide may be tandemly present.

[0037] In the present inventive polynucleotide the 3′ end of the enhancer, or first enhancer if there is more than one present, may be between about 100 to about 1000 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide or the first nucleotide of an intron or other untranslated leader sequence in the 5′ untranslated region in the case that the said region contains an intron or other untranslated sequence. In a more preferred, embodiment of the polynucleotide, the 3′ end of the enhancer, or first enhancer, is between about 150 to about 1000 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide or the first nucleotide of in the 5′ untranslated region, and in a still more preferred embodiment the 3′ end of the enhancer, or first enhancer, may be between about 300 to about 950 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide or the first nucleotide of an intron or other untranslated leader sequence in the 5′ untranslated region. In a yet more preferred embodiment, the 3′ end of the enhancer, or first enhancer, may be located between about 770 and about 790 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide or the first nucleotide of an intron or other untranslated leader sequence in the 5′ untranslated region.

[0038] In an alternative inventive polynucleotide, the 3′ end of the enhancer, or first enhancer, may be located between about 300 to about 380 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide or the first nucleotide of an intron or other untranslated leader sequence in the 5′ untranslated region, and in a preferred embodiment of this alternative polynucleotide the 3′ end of the enhancer, or first enhancer, is located between about 320 to about 350 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron or other untranslated leader sequence in the 5′ untranslated region.

[0039] In the polynucleotide according to the invention, the region upstream of the promoter from the EPSPS gene may comprise at least one enhancer derived from a sequence which is upstream from the transcriptional start of a promoter selected from the group consisting of those of the actin, rolDFd, S-adenosyl homocysteinase, histone, tubulin, polyubiquitin and plastocyanin genes and the CaMV35S and FMV35S genes.

[0040] Accordingly the present inventive polynucleotide may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of an actin gene.

[0041] Alternatively, the polynucleotide may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the rolDfd gene.

[0042] Alternatively, the polynucleotide may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of a histone gene.

[0043] Alternatively, the polynucleotide may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of a tubulin gene.

[0044] Alternatively, the polynucleotide-may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the FMV35S promoter and a second enhancer—comprising a transcriptional enhancing region derived from a sequence which is upstream is from the transcriptional start of the CaMV35S promoter.

[0045] Alternatively, the polynucleotide may comprise in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the CaMV35S promoter and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the FMV35S promoter.

[0046] Whatever the identity and juxtaposition of the various enhancers present in the polynucleotide, the nucleotides 5′ of the codon which constitutes the translational start of the EPSPS chloroplast transit peptide may be Kozack preferred. What is meant by tis is well known to the skilled man and will be further apparent from the examples below. Particularly preferred embodiments of the present inventive polynucleotide comprise up stream of the sequence encoding the EPSPS chloroplast transit peptide a sequence encoding a non-translated 5′ leader sequence derived from a relatively highly expressed gene, such as that of the glucanase, chalcone synthase and Rubisco genes.

[0047] The polynucleotide of the invention may also comprise a virally derived translational enhancer located within the non translated region 5′ of the genomic sequence which encodes the EPSPS chloroplast transit peptide. The man skilled in the art is aware of the identity of such suitable translational enhancers—such as the Omega and Omega prime sequences derived from TMV and that derived from the tobacco etch virus, and how such translational enhancers can be introduced into the polynucleotide so as to provide for the desired result of increased protein expression.

[0048] The polynucleotide according to the invention may further comprise regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, dessication, and herbicides. Whilst such a polynucleotide contemplates the herbicide resistance conferring gene being other than an EPSPS, such as glyphosate oxido-reductase (GOX) for example, the herbicide may be other than glyphosate in which case the resistance conferring genes may be selected from the group encoding the following proteins: phosphinothricin acetyl transferase (PAT), hydroxyphenyl pyruvate dioxygenase (HPPD), glutathione S transferase (GST), cytochrome P450, Acetyl-COA carboxylase (ACCase), Acetolactate synthase (ALS), protoporphyrinogen oxidase (PPO), dihydropteroate synthase, polyamine transport proteins, superoxide dismutase (SOD), bromoxynil nitrilase, phytoene desaturase (PDS), the product of the gdA gene obtainable from Alcaligeizes eutrophus, and known mutagenised or otherwise modified variants of the said proteins. In the case that the polynucleotide provides for multiple herbicide resistance such herbicides may be selected from the group consisting of a dinitroaniline herbicide, triazolo-pyrimidines, a uracil, a phenylurea, a triketone, an isoxazole, an acetanilide, an oxadiazole, a triazinone, a sulfonanilide, an amide, an anilide, an isoxaflutole, a flurochloridone, a norflurazon, and a triazolinone type herbicide and the post-emergence herbicide is selected from the group consisting of glyphosate and salts thereof, glufosinate, asulam, bentazon, bialaphos, bromacil, sethoxydim or another cyclohexanedione, dicamba, fosaamine, flupoxam, phenoxy propionate, quizalofop or another aryloxy-phenoxypropanoate, picloram, fluormetron, atrazine or another triazine, metribuzin, chlorimuron, chlorsulfuron, flumetsulam, halosulffron, sulfometron, imazaquin, imazethapyr, isoxaben, imazamox, metosulam, pyrithrobac, rimsulfuron, bensulfuron, nicosulfuron, fomesafen, fluroglycofen, KIH9201, ET751, carfentrazone, mesotrione, sulcotrione, paraquat, diquat, bromoxynil and fenoxaprop.

[0049] A particular embodiment of the polynucleotide according to the invention provides for resistance to both-glyphosate and a protoporphyrinogen oxidase (PPGO) inhibitor, in particular butafenicil, for which the corresponding resistance protein is a PPGO or an inhibitor resistant variant thereof. A particularly preferred construct encoding such a herbicide resistance conferring combination comprises the EPSPS encoding sequence of the invention in combination with a sequence which encodes a PPDK or PPS in combination with a PPGO inhibitor resistant PPGO enzyme encoding sequence—such sequences being directed to the chloroplast—if desirable—by their autologous transit peptides and being under the expression control of non-heterologous promoters if the protein encoding sequences are of plant as opposed to bacterial origin.

[0050] In the case that the polynucleotide comprises sequences encoding insecticidal proteins, these proteins may be selected from the group consisting of crystal toxins derived from Bt, including secreted Bt toxins; protease inhibitors, lectins, Xenhorabdus/Photorhabdus toxins. The fungus resistance conferring genes may be selected from the group consisting of those encoding known AFPs, defensins, chitinases, glucanases, and Avr-Cf9. Particularly preferred insecticidal proteins are crylAc, crylAb, cry3A, Vip 1A, Vip 1B, Vip3A, Vip3B, cysteine protease inhibitors, and snowdrop lectin. In the case that the polynucleotide comprises bacterial resistance conferring genes these may be selected from the group consisting of those encoding cecropins and techyplesin and analogues thereof. Virus resistance conferring genes may be selected from the group consisting of those encoding virus coat proteins, movement proteins, viral replicases, and anti-sense and ribozyme sequences which are known to provide for virus resistance; whereas the stress, salt, and drought resistance conferring genes may be selected from those that encode Glutathione-S-transferase and peroxidase, the sequence which constitutes the known CBF1 regulatory sequence and genes which are known to provide for accumulation of trehalose.

[0051] The polynucleotide according to the invention may be modified to enhance expression of the protein encoding sequences comprised by it, in that mRNA instability motifs and/or fortuitous splice regions may be removed, or crop preferred codons may be used so that expression of the thus modified polynucleotide in a plant yields substantially similar protein having a substantially similar activity/function to that obtained by expression of the protein encoding regions of the unmodified polynucleotide in the organism in which such regions of the unmodified polynucleotide are endogenous. The degree of identity between the modified polynucleotide and a polynucleotide endogenously contained within the said plant and encoding substantially the same protein may be such as to prevent co-suppression between the modified and endogenous sequences. In this case the degree of identity between the sequences should preferably be less than about 70%.

[0052] The invention still further includes a biological or transformation vector comprising the present inventive polynucleotide. Accordingly, by “vector” is meant, inter alia, one of the following: a plasmid, virus, cosmid or a bacterium transformed or transfected so as to contain the polynucleotide.

[0053] The invention still further includes plant material which has been transformed with the said polynucleotide or vector, as well as such transformed plant material which has been, or is, further transformed with a polynucleotide comprising regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, dessication, and herbicides.

[0054] The invention still further includes morphologically normal fertile whole plants which result from the crossing of plants which have been regenerated from material which has been transformed with the polynucleotide of the invention and plants which result from regeneration of material transformed with a polyncleotide which comprises a sequence which encodes a protein, such as a phosphoenolpyruvate synthase (PPS) or pyruvate orthophosphate di-kinase (PPDK) which proteins are capable of providing for elevated levels of phosphoenolpyruvate in the chloroplast. Such proteins are directed to the chloroplast by a suitable transit peptide—in the case of the PPDK enzyme preferably by the autologous peptide.

[0055] The invention still further includes morphologically normal fertile whole plants which contain the present inventive polynucleotide and which result from the crossing of plants which have been regenerated from material transformed with the present inventive polynucleotide or vector, and plants which have been transformed with a polynucleotide comprising regions encoding a CTP/PPS or CTP/PPDK, and/or regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, dessication, and herbicides. The invention also includes progeny of the resultant plants, their seeds and parts.

[0056] Plants of the invention may be selected from the group consisting of field crops, fruits and vegetables such as canola, sunflower, tobacco, sugar beet, cotton, maize, wheat, barley, rice, sorghum, mangel worzels, tomato, mango, peach, apple, pear, strawberry, banana, melon, potato, carrot, lettuce, cabbage, onion, soya spp, sugar cane, pea, field beans, poplar, grape, citrus, alfalfa, rye, oats, turf and forage grasses, flax and oilseed rape, and nut producing plants insofar as they are not already specifically mentioned, their progeny, seeds and parts.

[0057] Particularly preferred such plants include soybean, canola, brassica, cotton, sugar beet, sunflower, peas, potatoes, and mangel worzels.

[0058] The invention still further comprises a method of selectively controlling weeds in a field, the field comprising weeds and plants of the invention or the herbicide resistant progeny thereof, the method comprising application to the field of a glyphosate type herbicide in an amount sufficient to control the weeds without substantially affecting the plants. According to this method, one or more of a herbicide, insecticide, fungicide, nematicide, bacteriocide and an anti-viral may be applied to the field (and thus the plants contained within it) either before or after application of the glyphosate herbicide.

[0059] The invention still further provides a method of producing plants which are substantially tolerant or substantially resistant to glyphosate herbicide, comprising the steps of:

[0060] (i) transforming plant material with the polynucleotide or vector of the invention;

[0061] (ii) selecting the thus transformed material; and

[0062] (iii) regenerating the thus selected material into morphologically normal fertile whole plants.

[0063] The transformation may involve the introduction of the polynucleotide into the material by any known means, but in particular by: (i) biolistic bombardment of the material with particles coated with the polynucleotide; (ii) by impalement of the material on silicon carbide fibres which are coated with a solution comprising the polynucleotide; or (iii) by introduction of the polynucleotide or vector into Agrobacterium and co-cultivation of the thus transformed Agrobacterium with plant material which is thereby transformed and is subsequently regenerated. Plant transformation, selection and regeneration techniques, which may require routine modification in respect of a particular plant species, are well known to the skilled man. The thus transformed plant material may be selected by its resistance to glyphosate.

[0064] The invention still further provides the use of the present inventive polynucleotide or vector in the production of plant tissues and/or morphologically normal fertile whole plants which are substantially tolerant or substantially resistant to glyphosate herbicide.

[0065] The invention still farther includes a method of selecting biological material transformed so as to express a gene of interest, wherein the transformed material comprises the polynucleotide or vector of the invention, and wherein the selection comprises exposing the transformed material to glyphosate or a salt thereof, and selecting surviving material. The said material may be of plant origin, and may in particular be derived from a dicot selected from the group consisting of soybean, sugar beet, cotton and the Brassicas.

[0066] The invention still further includes a method for regenerating a fertile transformed plant to contain foreign DNA comprising the steps of:

[0067] (a) producing regenerable tissue from said plant to be transformed;

[0068] (b) transforming said regenerable tissue with said foreign DNA, wherein said foreign DNA comprises a selectable DNA sequence, wherein said sequence functions in a regenerable tissue as a selection device;

[0069] (c) between about one day to about 60 days after step (b), placing said regenerable tissue from step (b) in a medium capable of producing shoots from said tissue, wherein said medium may further contain a compound used to select regenerable tissue containing said selectable DNA sequence to allow identification or selection of the transformed regenerated tissue;

[0070] (d) after at least one shoot has formed from the selected tissue of step (c) transferring said shoot to a second medium capable of producing roots from said shoot to produce a plantlet, wherein the second medium optionally contains the said compound; and

[0071] (e) growing said plantlet into a fertile transgenic plant wherein the foreign DNA is transmitted to progeny plants in Mendelian fashion, characterised in that the foreign DNA is, or the selectable DNA sequence comprised by the foreign DNA comprises, the polynucleotide according to the invention, and the said compound is glyphosate or a salt thereof. The plant may be a dicot as indicated above—more preferably selected from soybean, canola, brassica, cotton, sugar beet, sunflower, peas, potatoes and mangel worzel, and the said regenerable tissue may consist of embryogenic calli, somatic embryos, immature embryos etc.

[0072] The present invention also includes a diagnostic kit comprising means for detecting the present inventive enzyme or polynucleotide or enzymes encoded by it, and therefore suitable for identifing tissues or samples which contain these. The polynucleotides can be detected by PCR amplification as is known to the skilled man—based on primers which he can easily derive from the enzyme encoding sequences which are disclosed in this application. The enzymes per se can be detected by, for example, the use of antibodies which have been raised against them for diagnostically distinguishing the antigenic regions which they contain.

[0073] The present invention will be further apparent from the following description taken in conjunction with the associated drawings and sequence listings.

[0074] Of the Sequences: SEQ ID No. 1 depicts Brassicia napus genomic DNA. 2 Bn EPSPS5 (PCR primer) 3 Bn EPSPS3 (PCR primer) 4 BnF1 (PCR primer) 5 BnF2 (PCR primer) 6 BnF3 (PCR primer) 7 BnF4 (PCR primer) 8 BnF5 (PCR primer) 9 BnF6 (PCR primer) 10 BnF7 (PCR primer) 11 BnF8 (PCR primer) 12 BnF9 (PCR primer) 13 BnF10 (PCR primer) 14 BnF11 (PCR primer) 15 BnF12 (PCR primer) 16 BnXho (PCR primer) 17 BnMUTBot (PCR primer) 18 BnMUTTop (PCR primer) 19 BnNde (PRC primer) 20 BnRBSEP (PCR primer) 21 Brasr 12 (PCR primer) 22 Brasr 11 (PCR Primer) 23 Bnapus start rev 24 Genome walker 1 25 Genome walker 2 26 CaMV343 (PCR primer) 27 CaMV46C (PCR primer) 28 BnGUSXMa (PCR primer) 29 FMV enhancer 30 CaMV35S enhancer 31 Soybean Genomic EPSPS Sequence clone 1/14 32 Soybean Genomic EPSPS Sequence clone 1/12 33 EPSPS 10 reverse (PCR primer) 34 EPSPS 4 forward (PCR primer) 35 SEQ ID No. 31 containing double mutation 36 SEQ ID No. 32 containing double mutation 37 FMV35S90 enhancer 38 FMV35S46 enhancer 39 Gm Term Bam (PCR primer) 40 Gm Term Eco (PCR primer) 41 BnMUT2PST (PCR primer) 42 BnMUTKPN (PCR primer) 43 GmRubPac (PCR primer) 44 GmRubbot (PCR primer) 45 GmRubtop (PCR primer) 46 GmRubKpn (PCR primer) 47 ZMPPDK1 (PCR primer) 48 ZMPPDK2 (PCR primer) 49 ECPPS1 (PCR primer) 50 ECPPS2 (PCR primer) 51-65 Motifs present in the stable EPSPS proteins of the invention

EXAMPLES

[0075] Methods useful for cloning, expressing and characterising the stable glyphosate-resistant EPSP synthases of the current invention are described herein

[0076] Stable glyphosate-resistant EPSPSs of the current invention are characterised as being stable (retaining>˜80% of their catalytic activity) after being incubated in a suitable buffer at 37 C for at least 4 hours. As exemplified below, enzyme stability experiments can suitably be carried out using substantially purified, part purified or crude—preparations of enzyme extracts (for example the latter are readily obtained as extracts of transgenic plants engineered to express the glyphosate-resistant EPSPS or, similarly, extracts of microbes engineered to express a transgene encoding the glyphosate-resistant EPSPS). Ideally, glyphosate-resistant enzymes are tested for stability both in a purified form and then as purified protein spiked back into a crude plant extract so as to test them under more realistic planta-like conditions. In such extracts, the enzyme activity due to glyphosate-resistant EPSPS can easily be discriminated from background susceptible endogenous EPSPS by testing activity over a range of glyphosate concentrations. At a discriminating concentration of glyphosate (e.g. 0.1 mM glyphosate in the presence of 0.1 mM PEP) virtually all of the measured activity will originate from the resistant enzyme

Example 1 Method for Identification of Stable Glyphosate-Resistant EPSP Synthases

[0077] In order to test the stability of a glyphosate-resistant EPSPS, a test solution of the enzyme (prepared as described below in buffer at pH ˜7.0-7.5 and in purified or part purified form) is heated to 37 C for 4-5 h. The glyphosate-resistant activity of the heated enzyme is then compared with the activity of a) a sample similarly prepared but kept at ice temperature and b) a similar sample but freshly prepared.

[0078] Stable glyphosate resistant enzymes of the current invention are characterised by the fact that, following incubation for 5 h at 37 C, they lose little, if any, of their original glyphosate-resistant catalytic activity (<20%, preferably <15% and more preferably <10%) relative to suitable controls when assayed as described below. Preferably the stability experiment is carried out using substantially pure enzyme although a very similar result will normally be obtained using crude preparations, or when pure protein is spiked back into crude extract. Methods suitably used for assay and preparation of enzyme extracts are further detailed below. The stability of the glyphosate-resistant EPSPS can suitably be assessed in a variety of other, essentially equivalent ways (for example by heating the enzyme at a slightly higher temperature for a shorter time or a lower temperature for a longer period . . . e.g at 25 C for 3 d).

Example 2 Method for assaying EPSPS Activity and Determination of Kinetic Constants

[0079] Assays are carried out generally according to the radiochemical method of Padgette et al 1987 (Archives of Biochemistry and Biophysics, 258(2) 564-573) with K+ ions as the major species of cationic counterion. Assays in a total volume of 501 μl, in 50 mM Hepes(KOH) pH 7.0 at 25° C., contain purified enzyme or plant extract (see below) diluted appropriately in Hepes pH 7.0 containing 10% glycerol, and 5 mM DTT, ¹⁴C PEP either as variable-substrate (for kinetic determinations) or fixed at 100 or 250 [M and shikimate 3 Phosphate (K+ salt) at 0.75 or 2 mM as indicated. Optionally, for assays of crude plant extracts, assays also contain 5 mM KF and/or 0.1 mM ammonium molybdate. Assays are started with the addition of ¹⁴C phosphoenolpyruvate (cyclohexylammonium+salt) and stopped after 2-10 minutes (2 minutes is preferable) with the addition of 50 μl of a solution of 1 part 1M acetic acid and 9 parts ethanol. After stopping, 20 μl is loaded onto a synchropak A×100 (25 cm×4.6 mm) column and chromatographed using isocratic elution with a 0.28M potassium phosphate pH 6.5 mobile phase flowing at 0.5 ml/min over 35 minutes. Under these conditions the retention times for PEP and EPSP are, depending on the individual columns, 19 and 25 minutes respectively. A CP 525TR scintillation counter is connected to the end of the AX 100 column. It is fitted with a 0.5 ml flow cell, and the flow rate of scintillant (Ultima Flo AP) is set at 1 ml/min. Relative peak areas of PEP and EPSP are integrated to determine the percentage conversion of labelled PEP to EPSP. Apparent K_(m) and Vmax values are determined by least squares fit to a hyperbola with simple weighting using the Grafit 3.09b from Erithacus Software Ltd. Km values are generally ascertained using 8-9 concentrations of variable substrate ranging from K_(m)/2-10 K_(m) and triplicate points. Except where specifically noted, data points are only included in the analysis where there is <30% conversion of substrate to EPSP.

[0080] Shikimate-3-Pi (S3P) is prepared as follows, To 7 mls of 0.3M TAPS pH 8.5 containing 0.05M Shikimate, 0.0665M ATP (Na salt), 10 mM KF, 5 mM DTT, and 0.05M MgCl₂.6H₂O, 75 μl of a 77 unit (μmol min⁻¹) ml⁻¹ solution of shikimate kinase is added. After 24 hrs at room temperature, the reaction is stopped by brief heating to 95° C. The reaction solution is diluted 50 fold in 0.01M Tris HCl pH 9, and chromatographed by anion exchange on Dowex 1×8-400, using a 0-0.34M LiCl₂ gradient. The S3P fractions are combined, freeze dried, and then redissolved in 7 mls distilled H₂O. 28 mls of 0.1M Ba(CH₃COOH)₂ and 189 mls of absolute ethanol are then added. This solution is left to stir overnight at 4° C. The resulting precipitate of tri-Barium S3P is collected and washed in 30 mls of 67% ethanol. The washed precipitate is then dissolved in ˜30 mls distilled H₂O. By adding K₂SO₄ the K⁺ salt of S3P is produced as required. Great care is taken to add a minimal excess of sulphate. The BaSO₄ precipitate is removed and the supernatant containing the required salt of S3P freeze dried. Each salt is weighed and analysed by proton NMR. S3P preparations so-prepared are >90% pure according to proton NMR and, according to their weights and integration of 31P NMR, contain only low residues of potassium sulphate.

Example 3 Preparation of Extracts of Plant Material Suitable for EPSPS Assay

[0081] Callus or plantlet material (0.5-1.0 g) is ground to a fine frozen powder in a liquid nitrogen-chilled mortar and pestle. This powder is taken up in an equal volume of a suitable chilled extraction buffer (for example, 50 mM Hepes/KOH buffer at pH 7.5 containing 1 mM EDTA, 3 mM DTT, 1.7 mM ‘pefabloc’ (serine protease inhibitor), 1.5 mM leupeptin, 1.5 mM pepstatin A, 10% v/v glycerol and 1% polyvinylpyrolidone), resuspended, mixed and centrifuged in a chilled centrifuige to bring down debris. The supernatant is exchanged down a chilled PD10 column of Sephadex G25 into 25 mM Hepes/KOH buffer at pH 7.5 containing 1 mM EDTA, 3 mM DTT and 10% v/v glycerol. Protein is estimated by the Bradford method standardised using bovine serum albumen. A portion of the extract is frozen in liquid nitrogen; a portion is assayed immediately.

Example 4 Method for Assaying EPSPS Activities in Crude Plant Materials and Discriminating the Proportion of the Total Which is Resistant to Glyphosate.

[0082] EPSPS assays of plant extracts are carried out, as described above, with 0.1 mM ¹⁴C-PEP and 0.75 mM shikimate-3-Pi either in the absence or the presence of 0.1 mM N-(phosphonomethyl)glycine. Under these assay conditions, the resistant forms of EPSPS of the current invention are estimated to be inhibited by <8.5% whilst the sensitive w/t form is essentially fully inhibited (>98%). Thus, the level of activity observed in the presence of glyphosate (A) is taken to represent ˜92% of the level of resistant enzyme derived from expression of the transgene whilst the level of susceptible w/t EPSPS is taken to be the total level of EPSPS activity observed in the absence of glyphosate minus the value of A×˜1.08. Because the Vmax of the mutant enzymes of the current invention are estimated to be, for example, only about a third of the Vmax of the w/t enzyme (and because the Km values for PEP of both w/t and mutant forms are estimated to be about 20 μM or less), the level of expression of the mutant enzyme polypeptide relative to the level of-expression of the endogenous w/t EPSPS is taken, to be about three fold higher than the ratio calculated on the basis of the ratio of their relative observed activities. The total level of EPSPS polypeptide expression (mutant+w/t) is also estimated by Western blotting.

Example 5 Cloning and Expression of w/t cDNA Encoding Mature Brassica napus EPSPS in E.coli

[0083]Brassica napus EPSPS cDNA is amplified using RT-PCR from RNA isolated from glass-house grown Brassica napus plants using Superscript RT from BRL according to the recommendation supplied by the manufacturer. PCR is performed using Pfu turbo polymerase from Stratagene according to the methods supplied by the manufacturer. Suitably designed oligonucleotide primers based on the known nucleotide sequence (EMBL accession X51475) are used in the amplification reaction and the reverse transcription steps. The PCR product is cloned into pCRBlunt II using Invitrogens Zero Blunt TOPO kit. The sequence of the insert is confirmed by sequencing and it is verified that the predicted open reading frame corresponds to that of the predicted mature chloroplastic Brassica napus EPSPS protein with the exception of the presence of an initiating Met. The cloned and verified EPSPS sequence is excised using suitable restriction enzymes as known in the art and the purified fragment is cloned into pET24a (Novagen) digested similarly. The recombinant clones are introduced into BL21 (DE3) a codon-optimised RP strain of E.coli supplied by Stratagene. The EPSPS protein is expressed in this strain following addition of 1 mM IPTG to the fermenter medium (LB supplemented with 100 ug/ml Kanamycin). The recombinant protein of the correct predicted mass is identified (i) on the basis of Coomassie staining of SDS gels of cell extracts and side by side comparison with Coomassie-stained gels of extracts of similar E.coli cells transformed with an empty pET24a vector and ii) by western analysis using a polyclonal antibody raised to previously-purified plant EPSPS protein.

Example 6 Cloning and Expression in E.coli of Glyphosate-Resistant Mutant Brassica napus EPSPS

[0084] The Brassica napus EPSPS cDNA in pCRBlunt is used as a template for two further PCR using primer pairs designed to introduce specific changes such that the resulting reaction product encodes a modified EPSPS protein wherein a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPLTAAV in the wild type enzyme such that the modified sequence reads GNAGIAMRSLTAAV. The sequence of Brassica napus EPSPS gene is known and methods for designing primers to effect this mutagenesis are well-known in the art.

[0085] The resultant PCR product is gel purified and cloned into pCRBlunt II using Invitrogens Zero Blunt TOPO kit. It is confirmed that the DNA sequence of the insert and its predicted open reading frame correspond to that of the predicted mature chloroplastic Brassica napus EPSPS protein (with the exception of the presence of an initiating Met) and also that the desired changes (the specific mutation of T to I and P to S at specific positions in the EPSPS sequence) are encoded. The thus cloned and verified B.napus EPSPS sequence is excised using suitable restriction enzymes and the purified fragment cloned into pET24a (Novagen) digested similarly. The recombinant clones are introduced into BL21 (DE3), a codon optimised RP strain of E.coli supplied by Stratagene. The EPSPS protein is expressed in this strain following addition of 1 mM IPTG to the fermenter medium (LB supplemented with 100 ug/ml Kanamycin). The recombinant protein of the correct predicted mass is identified i) on the basis of Coomassie staining of SDS gels of cell extracts and side by side comparison with Coomassie-stained gels of extracts of similar E.coli cells transformed with an empty pET24a vector and ii) by Western analysis using a polyclonal antibody raised to previously-purified plant EPSPS protein. This mutant form of Brassica napus EPSPS is purified and characterised as described herein.

Example 7 Purification and Characterisation of Mutant Brassica napus EPSPS

[0086] The mature mutant Biassica napus EPSPS protein is purified at ˜4 C as follows. 25 g wet weight of cells are washed in 50 ml of 0.1M Hepes/KOH buffer at pH 7.5 containing 5 mM DTT, 2 mM EDTA and 20% v/v glycerol. Following low-speed centrifugation, the cell pellet is resuspended in 50 ml of the same buffer but also containing 2 mM of ‘Pefabloc’ a serine protease inhibitor. Cells are evenly suspended using a glass homogenizer and then disrupted at 10000 psi using a Constant Systems (Budbrooke Rd, Warwick, U.K.) Basic Z cell disrupter. The crude extract is centrifuged at ˜30,000 g for 1 h and the pellet discarded. Protamine sulphate (salmine) is added to a final concentration of 0.2%, mixed and the solution left to stand for 30 nmin. Precipitated material is removed by centrifugation for 30 min at ˜30,000 g. Aristar grade ammonium sulfate is added to a final concentration of 40% of saturation, stirred for 30 min and then centrifuged at ˜27,000 g for 30 min. The pellet is resuspended in ˜10 ml of the same buffer as used for cell disruption, further ammonium sulfate is added to bring the solution to ˜70% of saturation, the solution is stirred for 30 min and centrifuged again to yield a pellet which is resuspended in ˜15 ml of S200 buffer (10 mM Hepes/KOH (pH 7.8) containing 1 mM DTT, 1 mM EDTA and 20% v/v glycerol). This is filtered (0.45 micron) loaded and chromatographed down a K26/60 column containing Superdex 200 equilibrated with S200 buffer. EPSPS-containing fractions detected on the basis of EPSPS enzyme activity are combined and loaded onto an xk16 column containing 20 ml of HP Q-Sepharose equilibrated with S200 buffer. The column is washed with S200 buffer and then EPSPS eluted within a linear gradient developed from 0.0M to 0.2M KCl in the same buffer. EPSPS elutes within a single peak corresponding to a salt concentration at or below approximately 0.1 M. EPSPS-containing fractions detected on the basis of EPSPS enzyme activity are combined and loaded onto a HiLoad xk26/60 column of Superdex 75 equilibrated with Superdex 75 buffer (25 mM Hepes/KOH (pH 7.5) containing 2 mM DTT, 1 mM EDTA and 10% v/v glycerol. EPSPS-containing fractions identified on the basis of enzyme activity are combined and loaded onto a 1 ml column of MonoQ equilibrated with the same, Superdex 75 buffer. The column is washed with starting buffer and EPSPS eluted as a single peak over the course of a 15 ml linear gradient developed between 0.0 and 0.2M KCl. EPSPS is obtained near (>90%) pure at this stage in the purification. Optionally, EPSPS is further purified by exchange into Superdex 75 buffer containing 1.0 M (Aristar) ammonium sulphate and loading onto a 10 ml column of phenyl sepharose equilibrated in the same buffer. EPSPS is eluted as a single peak early during the course of a linear gradient of declining ammonium sulphate developed between 1.0 and 0.0 M ammonium sulphate.

[0087] The purified mutant form of Brassica napus EPSPS, obtained by these or by similar methods and assayed as described above in the presence of 2 mM-shikimate-3-Pi, has an apparent Vmax of ˜5 μmol/min/mg and a Km for PEP of ˜25 μM. At 40 μM PEP, the IC50 value for the potassium salt of glyphosate is ˜0.6 mM. The estimated Ki value for potassium glyphosate of the mutant EPSPS is ˜0.45 mM.

Example 8 Cloning of genomic DNA encoding Brassica napus EPSPS

[0088] A Brassica napus genomic DNA fragment (SEQ ID No. 1), encoding EPSPS is known in the art (Gasser and Klee, 1990). PCR primers BnEPSPS5 (SEQ ID No.2) and BnEPSPS3 (SEQ ID No.3) are used to amplify the EPSPS gene from genomic DNA isolated from Brassica napus var. Westar. Pfu polymerase is used to perform the PCR using the following conditions:

[0089] 94° C. 5 min

[0090] 94° C. 1 min

[0091] 55° C. 30 s

[0092] 72° C. 12 min

[0093] The resulting 3.8 Kb product is cloned into pCR4Blunt-Topo and sequenced using the following primers: M13Forward, M13Reverse (Invitrogen), BnF1 (SEQ ID No.4), BnF2 (SEQ ID No.5), BnF3 (SEQ ID No.6), BnF4 (SEQ ID No.7), BnF5 (SEQ ID No.8), BaF6 (SEQ ID No.9), BnF7 (SEQ ID No. 10), BnF8 (SEQ ID No. 11), BnF9 (SEQ ID No. 12), BnF10 (SEQ ID No. 13), BnF11 (SEQ ID No. 14) and BnF12 (SEQ ID No. 15).

Example 9 Introduction of Mutations Into Genomic DNA Encoding BnEPSPS

[0094] The desired Thr-Ile and Pro-Ser mutations are introduced into the B. napus EPSPS gene by PCR using oligonucleotide primers containing codon changes so as to introduce the desired amino acid changes. Primers BnXho (SEQ ID No.16) and BnMUTBot (SEQ ID No.17) are used to amplify a desired region of EPSPS from Westar genomic DNA. Likewise, primers BnMutTop (SEQ ID No.18) and BnNde (SEQ ID No.19) are used to amplify an additional region from Westar genonic DNA. 1 ul of each of the PCR products is mixed and overlapping complementary sequences allowed to anneal. The products are then joined by PCR using primers BXho and BnNde. The resulting PCR product is cloned and sequenced to check for the inclusion of the double mutation. The Xho1/Nde1 fragment in the BnEPSPS clone is excised and replace with the cloned Xho1/Nde1 fragment containing the double mutant.

Example 10 Construct for Expression of Mutant B.napus EPSPS in Plants Having the Rubisco Leader Sequence Upstream of the Gene Encoding Mutant Brassica napus EPSPS.

[0095] The tobacco rubisco leader is introduced into the construct by PCR. Primers BnRBSEP (SEQ ID No.20) and Brasr12 (SEQ ID No.21) are used to amplify a product from 50 ng wildtype B. napus genomic DNA as template using Pfu-Turbo polymerase. The resulting PCR product is cloned into pCR4 blunt TOPO and clones are identified by restrictions digest that are orientated such as it may be excised as Not1 (from vector) and Xho1. The rubisco leader is then introduced into the mutated BnEPSPS clone as Not1/Xho1.

Example 11 Identification of the Brassica napus EPSPS promoter (useful for expression of EPSPS in plants) by genome walking

[0096] Increased lengths of upstream or downstream sequence of any plant gene may be obtained using the genome walking kit as supplied and directed by Clontech. The primers depicted in SEQ ID Nos 22 and 23 (Bras r11 and B.napus start rev) are used to obtain upstream sequence of the Brasicca napus EPSPS gene using Brasicca napus genomic DNA according to the methods described in the protocol accompanying the genome walker kit.

[0097] The Bras r11 (SEQ ID No. 22) primer is used in conjunction with the API primer supplied in the genome walker kit and the Bnapus start rev primer is used with the AP2 primer supplied with the genome walker kit. Products are cloned into pCR-TOPO using a TOPO TA Cloning kit from Invitrogen according to the manufacturers instructions. PCR using M13 forward and reverse primers is performed using Ready to Go Beads from Pharmacia to ascertain which clones contain inserts of the correct size. A number of these clones are used to make DNA preps and these DNAs are then used to determine the nucleotide sequence of the inserts.

[0098] A second set of primers (SEQ ID Nos.24 and 25 respectively) is used for a further walk as shown below:

[0099] Genome walker 1 (SEQ ID No.24) with the API primer

[0100] Genome walker 2 (SEQ ID No.25) with the AP2 primer

[0101] Additional genomic digests are performed in addition to those recommended by Clontech's protocols. These digests include Alu I, Hae III, Hinc II and Rsa I. These digested DNAs are then treated identically to the other digests performed as described by the protocols accompanying the Genome walking kit. This is done to increase the chance of getting a correct and long PCR product. Again the PCR products are cloned into pCR-TOPO using a TOPO TA Cloning kit from Invitrogen according to the manufactures instructions and sequence determination is performed on random clones obtained from each cloned product that contain inserts of the correct size. The sequence of the inserts are determined. Approximately 1 kb of sequence upstream form the translational start site of the Brasicca napus EPSPS is obtained that is contiguous with the published sequence.

Example 12 Constructs for Expression of Mutant Brassica napus EPSPS in Plants

[0102] The 35S enhancer is amplified from vector pMJB1 (FIG. 1) by PCR using primers CaMV343 and CaMV46C (SEQ ID Nos.26 and 27 respectively) The PCR product is cloned into vector pCR4Blunt-TOPO and sequenced. The desired promoter, obtained as described in the previous example is amplified from B. napus Westar genomic DNA using a 5′ primer containing a Sph1 site and BnGUSXma (SEQ ID No.28)

[0103] The PCR product is digested directly with Sph1 and Xma1 and ligated into the pCR4Blunt-TOPO vector containing the 35S enhancer as Sph1/Xma1 (partial digest with Sph 1). The CaMV35S enhancer fused to the BnEPSPS promoter is then excised from pCR4-Blunt using Not1 (from vector) and Xma 1 and cloned into the PCR4Blunt vector containing the tobacco rubisco leader and mutated B. napus EPSPS gene. The FMV enhancer (SEQ ID No.29) or the CaMV35S enhancer (SEQ ID No.30) is synthesised chemically and subcloned into vector pCR4 Blunt TOPO. The FMV enhancer is excised from PCR4-Blunt as Not1/Sac1 and ligated into the CaMV35S enhancer/B. napus promoter/rubisco leader/B. napus EPSPS as Not1/Sac1. The final construct is shown in FIG. 2. The whole expression cassette may be excised using EcoR1 and ligated into a suitable vector for plant transformation.

Example 13 Plant Transformation and Regeneration

[0104] The expression cassette is excised from the pFCBnEPSPS vector using EcoR] and ligated into, for example, a binary vector pBin19 at the unique EcoR1 restriction site. The binary vector, containing the desired expression cassette transformed into Agrobacterium tumefaciens strain LBA 4404 using the freeze thaw method of transformation provided by Holsters et al., 1978. Tobacco transformation and whole plant regeneration is performed using Nicotiana tabacum var. Samsun according to protocols in Draper et al (Plant Genetic Transformation, Blackwell Sci. Pub. 1989). Transformation events are selected on MS-media containing kanamycin. Alternatively pFCBnEPSPS, or other constructs capable of delivering glyphosate resistance in plants by the expression of a glyphosate resistant EPSPS gene from soybean may be introduced into plants directly without using Agrobacterium mediated techniques as described for Soybean.

[0105] Constructs are transformed into regenerable embryogenic soyabean tissues using either biolistic type approaches (e.g Santarem E R, Finer, J. J (1999) ‘Transformation of soyabean (Glycine max (L.) Merrill) using proliferative embryogenic tissue maintained on a semi-solid medium’ In vitro Cellular and Developmental Biology-Plant 35, 451-455; U.S. Pat. No. 5,503,998, U.S. Pat. No. 5,830,728)or via infection with Agrobacterium (e.g. U.S. Pat. No. 5,024,944, U.S. Pat. No. 5,959,179). Regenerable embryogenic soyabean tissues are derived, for example, from the cotyledons of immature embryos or other suitable tissues.

[0106] Proliferative embryogenic tissue can, for example, be maintained on a semi-solid medium. Such tissue, is, for example obtained in the following way. Immature zygotic embryos which are 3-4 mm long are isolated from pods of, for example, Glycine max (L.) Merrill, 2-3 weeks after flower formation. Pods can be checked for the presence of embryos of the correct length and maturity by ‘backlighting’. Pods are then sterilized. Immature embryos are removed and the axis removed from each. Immature embryos are then plated on ‘D40-Lite’ semi-solid (0.2% gelrite) MS salts medium at pH 7.0 containing B5 vitamins, 3% sucrose and 40 mg/l 2,4-D for 3-4 weeks. For proliferation of embryos the material is then transferred to ‘D20’ MS salts medium at pH 5.7 containing B5 vitamins, 3% sucrose, 20 mg/l 2,4-D and 0.2% Gelrite. Material with bright green globular proliferative embryos is selected and subcultured every 2-3 weeks.

[0107] For bombardment, 20-25 clumps/plate of tissue are selected (subcultured 4-5 days prior to bombardment) and arranged in the centre of the dish containing D20 medium. The tissue is dried for 15 min by uncovering for 15 minutes under a sterile hood. Gold particles coated in DNA construct (coated, for example, using methods described in the references above) are twice bombarded into the tissue on D20 medium using any one of a large number of commercially available guns. By way of further example a PDS 1000 particle gun is used. Particles may be prepared and coated with DNA in a similar manner to that described by Klein et al 1987, Nature, 327, 70-73. Alternatively, for example, 60 mg of gold or tungsten particles (1.0 lm) in a microcentriftge tube are washed repeatedly in HPLC-grade ethanol and then, repeatedly, in sterile water. The particles are resuspended in 1 ml of sterile water and dispensed into 50 μl aliquots in microcentrifuge tubes. Gold particles are stored at 4 C, tungsten particles at −20 C. 3 mg of DNA are added to each aliquot of (defrosted) particles and the tubes are vortexed at top speed. Whilst maintaining near continuous vortexing, 50 μl of 2.5M CaCl₂ and 20 μl of 0.1M spermidine is added. After 10 minutes of further vortexing, samples are centrifuged for 5 seconds in an eppendorf microcentrifuge, the supernatant is drawn off and the particles washed in successive additions of HPLC-grade ethanol. The particles are thoroughly resuspended in 60 μl of ethanol and then dispensed in 10 μl aliquots onto the surface of each macrocarrier to be used in the PDS1000 particle gun. Components of the PDS1000 particle gun are surface sterilised by immersion in 70% ethanol and air-drying. Target plates prepared, as described above, with tissue arranged into an 2.5 cm disc are placed 6 cm from the stopping screen. Suitably chosen rupture discs are then used for bombardment.

[0108] One week after bombardment, all tissue clumps are transferred onto D20 medium, buffered to pH 5.7, containing a suitable selective concentration of glyphosate between 0.05 and 5 mM. After an additional 3-4 weeks all tissue is transferred to fresh D20 medium containing an increased concentration of glyphosate within this concentration range. After a further 3-4 weeks, living tissue is selected and subcultured on every 3-4 weeks in similar D20 medium containing glyphosate. Alternatively, in the case that some other selectable marker than glyphosate is also present then selections may be made as appropriate (e.g using increasing concentrations of hygromycin). Growing sections are thus maintained and, given enough tissue, may be analysed by PCR to confirm that they are transgenic for the desired DNA.

[0109] In order to develop and mature embryos, tissue clumps are placed onto M6 medium which comprises MS salts at pH 5.7 containing B5 vitamins, 6% maltose and 0.2% gelrite. 6-9 clumps are placed in a tall dish at 23° C. After 3-4 weeks, embryos elongate and can be separated and transferred to another round of incubation on M6 medium. After 4-6 weeks, embryos are cream-coloured and ready for desiccation. 9 such cream-coloured embryos are placed in a dry Petri dish, sealed with parafilm and placed onto a shelf for 2-3 days. Embryos should be somewhat flaccid and not “crispy-crunchy”.

[0110] Dessicated embryos can be germinated by plating onto OMS (growth regulator-free MS medium). Following germination which normally occurs within a week plants are transferred to larger boxes and, once there is sufficient root and shoot formation, thence to soil. To prevent fungal contamination it is advisable to wash OMS from the roots with is distilled water. Plants may be kept and grown under high humidity and, initially, under 24 hour lighting. Plants may be grown until about 2 feet tall under 24 hour lighting and then encouraged to flower and form pods through a shift to a 16 hour lighting regime. Seeds are collected and progeny grown on, crossed and backcrossed into order to move the transgenes into the desired plant background using the normal methods of plant breeding. Plants are routinely analysed for the presence and expression of transgenes using the normal methods of molecular biology including analysis by PCR, Southern, Western, ELISA and enzyme assay techniques.

Example 14 Methods of Obtaining, Genes Encoding Stable Glyphosate Resistant EPSPs

[0111] In one embodiment of the current invention, glyphosate resistant EPSPS genes suitable for expression in E.coli are constructed, as for example, described herein where, in the coding sequence a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the following conserved region GNAGTAMRPL in the wild type enzyme such that the modified sequence reads GNAGIAMRSL.

[0112] Stable glyphosate-resistant EPSP synthases of the current invention and genes encoding these are then obtained by generating a wide range of variants by a process of random or partially random mutagenesis (for example using chemical or UV mutagenesis, by using a non-proof reading DNA polymerase (e.g. in a strain such as XLI red) or by using any one of a number of ‘directed evolution’ approaches (e.g as reviewed by Kuchner and Arnold, 1997 in TIBTECH, 15, 523-530 or described by Stemmer (1994) in PNAS, 91, 10747-10751) and selecting genes expressing EPSPSs which are stable and which remain glyphosate resistant. Suitable means of selection include, for example, expression of mutated genes (e.g from a weak constitutive promoter) in an Aro A-strain of E.coli grown at elevated temperatures (e.g 37-42 C) and selecting those transformants most capable of growth in minimal medium (optionally also containing glyphosate). Alternatively, a non-aro A host strain might be used (preferably e.g. rec A) provided that the medium contains a selective concentration of glyphosate. The skilled man will recognise that many methods of mutagenesis and selection could be used within the ambit of the current invention.

Example 15 Stable Glyphosate-Resistant EPSPSs and Genes Encoding Them

[0113] The stable double mutant form of Brassica napus EPSPS is one example of the current invention. The skilled man will recognise that other examples of such EPSPSs of the current invention and genes encoding them can be cloned, isolated and characterised using methods the same or similar to those described above.

[0114] In EPSPSs and the EPSPS gene sequences of the current invention, the coding sequence at a first position is mutated so that the residue at this position is Ile rather than Tlr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into BPSPS sequences which comprise the following conserved region GNAGTAMRPL in the wild type enzyme such that the modified sequence reads GNAGIAMRSL.

[0115] EPSPS protein sequences of the current invention are further characterised in that they DO NOT comprise a region having the sequence K(A/V)AKRAVVVGCGGKFPVE

[0116] EPSPS protein sequences of the current invention are furter characterised in that they comprise at least one of the amino acid sequence motifs listed below in (i)→(viii). (i) ALLMZAPLA where Z is NOT S or T (ii) EIEIZDKL where Z is NOT V (iii) FG(V/I)(K/S)ZEH where Z is NOT V (iv) AL(K/R)ZLGL where Z is NOT R (v) GLXVEZ₁DXZ₂XXXA(I/V)V where Z₁ is NOT T and/ or Z₂ is NOT E (vi) ITPPZ₁K(L/V)(K/N)Z₂ where Z₁ is NOT K and/ or Z₂ is NOT T (vii) TIZ(D/N)PGCT where Z is NOT N or L (viii) (D/N)YFXVLXZXX(K/R)H where Z is NOT R

[0117] wherein X is any amino acid and Z, Z1, and Z2 are any amino acid other than those indicated.

[0118] Furthermore it is preferred, for EPSPS genes and proteins of the current invention, that the protein sequence comprise at least one of the sequence motifs i), ii) iii), v) and vi), preferably, at least two of these.

[0119] Furthermore, in amino acid sequence motif i) Z is preferably A, in sequence motif ii) Z is preferably I, in sequence motif iii) Z is preferably A, in sequence motif iv) Z is preferably K, T or A, in sequence v) Z₁ is preferably R or A and less preferably D or E whilst Z₂ is preferably V or A and less preferably T, in sequence motif vi) Z, is preferably E or A whilst Z₂ is preferably P, I or V, in sequence motif vii) Z is preferably R or K and in sequence motif viii) Z is preferably T or S and less preferably is Q.

[0120] Furthermore, some of the EPSPS protein sequences of the current invention are characterised in that they comprise at least one of the following sequences: (I/V)VEGCGG(I/L/Q)FP(V/AIT)(S/G) or (I/V)VVGCGG(I/L/Q)FP(V/A/T)E or (I/V)VVGCGG(I/L/Q)FP(V/A/T)(S/G) or (L/V)VVGCGGKFP(V/A/T)(S/G)or (I/V)VEGCGGKFP(V/A/T)E or (I/V)VEGCGG(I/L/Q)FP(V/A/T)E or (I/V)VEGCGGKFP(V/A/T)(S/G)

[0121] Furthermore EPSPS sequences of the current invention are preferably derived from dicotyledenous plants

EXAMPLE 16 Stable Glyphosate-Resistant EPSPSs Derived from Soyabean

[0122] Preferred examples of the current invention are the EPSPS protein sequences and the DNA sequences which encode these which are derived from soyabean (see for example EPSPS gene SEQ ID Nos 33 and 34) and which are then optionally modified according to Example 15 to yield a stable glyphosate resistant EPSP synthase.

[0123] Particularly preferred examples are EPSP synthase genes derived from soyabean in which:

[0124] (a) the coding sequence at a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the following conserved region GNAGTAMRPL in the wild type enzyme such that the modified sequence reads GNAGIAMRSL,

[0125] And

[0126] (b) the DNA coding sequence may be further modified in accord with Example 15 so that the encoded protein comprises at least one and preferably two or more of the amino acid sequence motifs ii), iii), v) and viii).

Example 17 Cloning of a Soybean Partial Length cDNA Encoding EPSPS

[0127] Soybean RNA is isolated using Trizol™ reagent as described by Gibco BRL, and first-strand cDNA synthesised using Superscript II (Gibco BRL) using protocols provided by the manufacturer with the degenerate primer EPSPS 10 reverse (SEQ ID No.35). PCR is performed using ready to go PCR beads supplied by AmershamPharmacia™ according to the protocol supplied by the manufacturer using the reverse transcribed soybean first-strand cDNA product as a template and the primers EPSPS 4 forward (SEQ ID No.34) and EPSPS 10 reverse (SEQ ID No.33).

[0128] The following PCR conditions are used:

[0129] 1. 94° C. 3 minutes for 1 cycle

[0130] 2. 94° C. 45 seconds

[0131] 50° C. 30 seconds

[0132] 72° C. 1 minute for 25 cycles

[0133] 3. 72° C. 10 minutes for 1 cycle.

[0134] The product obtained of approximately 1 kb is cloned into pCR2.1 using a TOPO TA cloning Kit (Invitrogen) according to the manufacturer's recommendations. Colonies are picked at random and are selected for further work via plasmid preparation with the QIAprep Mini-Prep Kit (Qiagen), followed by digestion with Eco RI to show the size of the insert in these clones. Clones containing the expected 1 kb insert are progressed. The polynucleotide sequence of selected clones is determined using an ABI 377 automated sequencer. Database searching is performed using the Blast algorithm (Altschul et al., 1990) and indicates that the majority of sequenced clones contain partial length cDNAs exhibiting high homology toward known plant EPSPS sequences.

Example 18 Isolation of a Genomic Polynucleotide Sequence Encoding Soybean EPSPS

[0135] A soybean genomic library constructed in Lambda Fix II is purchased from Stratagene and-, 1,000,000 clones are plated out according to the suppliers protocols. Hybond N+ filters are used to make lifts from the library plates and these were processed according to the protocols supplied by AmershamPharmacia and Molecular Cloning—a laboratory manual (Sambrook et al., 1989). UV cross linking of the DNA to the membrane is carried out using a UV Stratalinker (Stratagene). The soybean EPSPS cDNA probe is prepared by digesting the clone containing the soybean EPSPS partial length cDNA sequence with Eco RI and purifying the 1 kb product by agarose gel electrophoresis. The probe is labelled with ³²P dCTP using a Ready-To-Go™ DNA labelling kit (AmershamPharmuacia). The filters are prehybridised and hybridised in Rapid-Hyb Buffer (Amersham Pharmacia). Washes are performed using 0.1×SSPE, 0.5% SDS at 65° C. The filters are then wrapped in Saran wrap and exposed to film in a cassette containing an intensifying screen as described in Molecular Cloning—a laboratory manual (Sambrook et al., 1989).

[0136] Hybridising plaques are picked into SM buffer, replated at lower density and rescreened through 2 further rounds of purification. Phage DNA is recovered from plaque pure phage stocks using methods well known in the art (Sambrooke et al. 1989). The recovered phage DNA is digested with Not 1 and the genomic DNA subcloned into pBluescript. The resulting vector is transformed into TOP 10 E.coli. The resulting clones are sequenced using the Genome Priming System (NEB) using protocols provided by the manufacturer. Briefly, sufficient batches of 96 GPS events are selected and DNA prepared using a Qiagen™ Biorobot. The DNA was sequenced with the GPS-S and GPS-N primers as supplied by NEB using an ABI 377 automated sequencer. Sequence data are analysed using Seqman (DNASTAR Inc). The gene encoding EPSPS is identified by homology to known EPSPS genes using the Blast algorithm. The sequence of two contigs containing sequences showing high homology to known EPSPS are given in SEQ ID No.37 and SEQ ID No.38 and are termed GnEPSPS1/14 and GmEPSPS12 respectively. A schematic representation of these genes is given in FIG. 3 and FIG. 4.

[0137] The person skilled in the art will know that there could be other EPSPS genes present in soybean and that these may be isolated and the nucleotide sequence determined using similar methodologies as described in this example.

Example 19 Production of Plant Transformation Vector Harbouring the Soybean EPSPS Gene

[0138] The two enhancer combinations FMV35S90 (SEQ ID No.37 and FMV35S46 (SEQ ID No.38) are synthesised chemically and subcloned into vector pTCV1001 (FIG. 5) using Hind III/Pac 1. The soybean EPSPS terminator, and a small region of the coding sequence, are obtained by PCR using the primers GmTermBam (SEQ ID No.39) and GmTermEco (SEQ ID No.40) using clone GmEPSPS 1/14 as template. The PCR product is cloned into pCR4-Blunt-TOPO, sequenced, and excised using Pst1 and EcoR1 and ligated into the pTCV10O1 vector containing the FMV/CaMV35S enhancers. Finally, the Pac1:BamH1 is DNA fragment containing the majority of the soybean EPSPS gene in either GniEPSPS 1/14 is excised and cloned into the pTCV1001 vector comprising both the enhancers and terminator.

Example 20 Introduction of Mutation Into EPSPS Gene

[0139] The desired Thr to Ile and Pro to Ser mutations required to increase tolerance to glyphosate are inserted into the construct in the following manner. Primer BnMUT2PST (SEQ ID No.41), which contains the nucleotide changes that give rise to the desired amino-acid mutation, is used in conjunction with primer BnNUTKPN (SEQ ID No.42) in PCR with pfu-TURBO polymerase (Stratagene) with GmEPSPS 1/14 as template. The PCR product, now containing the desired mutation, is cloned into pCR4-Blunt-TOPO and sequenced. It is then excised as Kpn 1 Pst 1 and used to replace the corresponding fragment in the construct in pTCV1001 containing WT sequence. The final vector is termed pTCVGMEPSPS (FIG. 6).

Example 21 Introduction of 5′ UTL

[0140] An additional 5′ UTL, such as that from the small subunit of ribulose biphosphate carboxylase/oxygenase (Rubisco) or tobacco glucanase can be inserted into the construct by PCR. In addition the context surrounding the AUG translation initiation codon is optimised to give the consensus Kozak sequence ACCAUGG. With regard the SSU rubisco leader, primers GmRubPac (SEQ ID No.43) and GmRubbot (SEQ ID No.44) are used to introduce the soybean rubisco 5′ UTL into 5′ UTL of the soybean EPSPS gene. GmRubTop (SEQ ID No.45) and GmRubKpn (SEQ ID No.46) are then used to introduce the soybean rubisco 5′ UTL into the first exon of the soybean EPSPS gene. The two PCR products are then joined, by PCR using primers GmubPac and GmRubKpn and the resulting product cloned into pCR4Blunt-TOPO and sequenced. Once the authenticity of the PCR product is confirmed it is excised from the PCR4 vector as Pac1:Kpn1 and used to replace the Pac1/Kpn1 restriction fragment in vector pTCVGMEPSPS.

[0141] These examples outline the construction of a DNA sequence comprising two enhancers fused to a soybean EPSPS gene containing specific mutations in the coding sequence that is capable of producing a glyphosate resistant EPSPS enzyme in plants. The person skilled in the art will know that enhancers may be introduced at various distances up stream from the promoter and transcriptional start site to act to enhance the rate and/or amount of transcription of the double mutant EPSPS soybean gene in plant cells. The distance may have to be determined empirically for each individual gene. This involves making a number of constructs where the enhancers are fused at different distances from the transcriptional start of the double mutant EPSPS soybean gene and introducing these constructs into plant material and assaying the material for resistance to selecting concentrations of glyphosate. The person skilled in the art will also know that enhancer choices are not restricted to CaMV 35S and FMV enhancers, but may also include enhancers from any gene that is highly expressed in plants including inter alia, enhancers from actin genes, ubiquitin genes, mannopine, nopaline and octopine synthase genes, genes from commelina yellow virus and other plant viruses expressed in plants such as potato virus Y and X coat proteins. The choice of 5′ UTR may not be restricted to soybean small subunit rubisco and leader from other genes may be used.

Example 22 Plant Transformation and Regeneration

[0142] The expression cassette is excised from the pTCVGMEPSPS vector using Xma 1 and ligated into a binary vector pBin19 at the unique Xma 1 restriction site. The binary vector, containing the desired expression cassette transformed into Agrobacterium tumefaciens strain LBA 4404 using the freeze thaw method of transformation provided by Holsters et al., 1978. Tobacco transformation and whole plant regeneration are performed using Nicotiana tabacum var. Samusun according to protocols in Draper et al (Plant Genetic Transformation, Blackwell Sci. Pub. 1989). Transformation events are selected on MS-media containing kanamycin.

[0143] Alternatively PTCGMEPSPS, or other constructs capable of delivering glyphosate resistance in plants by the expression of a glyphosate resistant EPSPS gene from soybean may be introduced into plants directly without using Agrobacterium mediated techniques as described for Soybean in a number of references including the following: Physiol. Plant. (1990), 79(1), 210-12; USP-5,968,830; WO-0042207; and USP-5,959,179 and as described in Example 13.

Example 23 Analysis of Transgenic Plants

[0144] PCR Analysis of Transformants

[0145] Leaf samples were taken from transformed lines and DNA extracted according to known methods. Oligonucleotide primers are designed to specific regions within the transgene to enable its detection in the plant material tested.

[0146] RNA Analysis

[0147] The presence of mRNA encoding the transgene is detected within the plant using Northern Blot hybridisation. Total RNA is extracted from leaf tissue using Tri-reagent and protocols provided by the manufacturer (Sigma™). Blots are prepared using existing procedures and probed using radio-labelled soybean EPSPS cDNA.

[0148] Protein Analysis

[0149] The presence of recombinant protein in the transgenic plant is determined using Western blotting procedures with antibodies raised to recombinant soybean EPSPS using standard protocols.

[0150] Enzyme Assays

[0151] Resistant EPSPS activity is detected in plants using ¹⁴C radiolabelled substrates and detection of products by HPLC.

[0152] Herbicide Tolerance Tests

[0153] Following tissue culture, transgenic plants are transferred to 5 inch pots containing John Innes potting compost no. 3. The plants are allowed to acclimatise (approx. 2 weeks) in the greenhouse and formulated glyphosate applied at various concentrations to the aerial tissue using a track spayer. Visual assessment of the transformed plants to identify those that are resistant to glyphosate is performed 21 days post application.

Example 24 Introduction of Plastid Targeted Pyruvate Orthophosphate Di-Kinase (PPDK) or Phosphoenolpyruvate Synthase (PPS) Constructs.

[0154] The cDNA encoding PPDK from maize (EMBL Accession J03901), containing its autologous transit peptide sequence, is amplified by RT-PCR from maize tissue using primers ZMPPDK1 (SEQ ID No. 47) and ZMPPDK2 (SEQ ID no. 48). The RT-PCR product is cloned into the vector pCR2.1 TOPO and sequenced to check for authenticity. The maize PPDK gene is excised from the pCR2.1 vector, as a Nco 1/Kpn 1 fragment and ligated into similarly digested pMJB1 (FIG. 1). The plant expression cassetee is then subcloned into the pTCVGMEPSPS cassette (FIG. 6) prior to further plant transformation. Other PPDK genes, such as that encoding a cold-stable PPDK from Flayeria byownii (EMBL accession AAQ94645) or form rice can be engineered using a similar strategy. Likewise, the gene encoding PPS in E. coli (EMBL Accession X59381) is amplified by PCR using oligos ECPPS 1 (SEQ Id No. 49) and ECPPS2 (SEQ ID No. 50). The PCR product is cloned into plant expression cassette containing a plant operable promoter (such as the cauliflower mosaic virus 35S promoter), a chloroplast transit signal sequence (such as that from the small subunit of rubisco) and a terminator (such as NOS).

[0155] Sequence Listing

[0156]Brassica napus Genomic DNA Encoding an EPSPS (SEQ ID No. 1) Brassica napus genomic DNA encoding an EPSPS (SEQ ID No.1) gcatgcagatcttaaaggctettttccagtctcacctaccaaaactataagaaaatccacttgctgtctgaaatagccgacggataaag tacttaagacgtggcacattattattgactactagaaaaaaaactcatacaccatcgtaggagttggggggtgaagaatttgatgggtg cctctcccccccccactcaccaaactcatgttctgtaaagccgtcactacaacaacaaaggagacagacagttctatagaaaagctttc aaattcaatcaatggcgcaatctagcagaatctgccatggcgtgcagaacccatgtgttatcatctccaatctctccaaatccaaccaaa acaaatcacctttctccgtctccttgaagacgcatcagcctcgagcttcttcgtggggattgaagaagagtggaacgatgctaaacggtt ctgtaattcgcccggttaaggtaacagcttctgtttccacgtccgagaaagcttcagagattgtgcttcaaccaatcagagaaatctcgg gtctcattaagctacccggatccaaatctctctccaatcggatcctccttcttgccgctctatctgaggtacatatacttgcttagtgttaggc ctttgctgtgagattttgggaactatagacaatttagtaagaatttatatataatttttttaaaaaaaatcagaagcctatatatatttaaatttttc caaaatttttggaggttataggcttatgttacaccattctagtctgcatctttcggtttgagactgaagaattttattttttaaaaaattattatag ggaactactgtagtggacaacttgttgaacagtgatgacatcaactacatgcttgatgcgltgaagaagctggggcttaacgtggaacg tgacagtgtaaacaaccgtgcggttgttgaaggatgcggtggaatattcccagcttccttagattccaagagtgatattgagttgtacctt gggaatgcaggaacagccatgcgtccactcaccgctgcagttacagctgcaggtggcaacgcgaggtaaggttaacgagttttttgtt attgtcaagaaattgatcttgtgtttgatgcttttagtttggtttgttttctagttatgtacttgatggggtgcctagaatgagggaaagacctat aggagatttggttgttggtcttaagcagcttggtgctgatgttgagtgtactcttggcactaactgtcctcctgttcgtgtcaatgctaatggt ggccttcccggtggaaaggtgatcttcacatttactctatgaattgtttgcagcagtctttgttcatcacagcctttgcttcacattatttcatct tttagtttgttgttatattacttgatggatctttaaaaaggaattgggtctggtgtgaaagtgattagcaatctttctcgattccttgcagggcc gtgggcattactaagtgaaacattagcctattaacccccaaaatttttgaaaaaaatttagtatatggccccaaaatagtttttaaaaaatta gaaaaacttttaataaatcgtctacagtcccaaaaatcttagagccggccctgcttgtatggtttctcgattgatatattagactatgttttga attttcaggtgaagctttctggatcgatcagtagtcagtacttgactgccctcctcatggcagctcctttagctcttggagacgtggagatt gagatcattgataaactgatatctgttccatatttgaaatgacattgaagttgatggagcgttttggtgttagtgccgagcatagtgatag ctgggatcgtttctttgtcaagggcggtcagaaatacaagtaatgagttcttttaagttgagagttagattgaagaatgaatgactgattaa ccaaatggcaaaactgattcaggtcgcctggtaatgcttatgtagaaggtgatgcttctagtgctagctacttcttggctggtgctgccatt actggtgaaactgttactgtcgaaggttgtggaacaactagcctccaggtagtttatccactctgaatcatcaaatattatactccctccgtt attaattagcaaaatcaaacaaaaattatattaaataatgtaaaattcgtaatttgtgtgcaaataccttaaaccttatgaaacggaaacctta tgaaacagagggagtactaattttataataaaatttgattagttcaaagttgtgtataacatgttttgtaagaatctaagctcattctctttttatt ttttgtgatgaatcccaaagggagatgtgaaattcgcagaggttcttgagaaaatgggatgtaaagtgtcatggacagagaacagtgtg actgtgactggaccatcaagagatgcttttggaatgaggcacttgcgtgctgttgatgtcaacatgaacaaaatgcctgatgtagccatg actctagccgttgttgctctctttgccgatggtccaaccaccatcagagatggtaaagcaaaaccctctctttgaatcagcgtgttttaaaa gattcatggttgcttaaactctatttggtcaatgtagtggctagctggagagttaaggagacagagaggatgattgccatttgcacagag cttagaaaggtaagtttccttttctctcatgctctctcattcgaagttaatcgttgcataactttttgcggttttttttittgcgttcagcttggagc tacagtggaagaaggttcagattattgtgtgataactccaccagcaaaggtgaaaccggcggagattgatacgtatgatgatcatagaa tggcgatggcgttctcgcttgcagcttgtgctgatgttccagtcaccatcaaggatcctggctgcaccaggaagactttccctgactactt ccaagtccttgaaagtatcacaaagcattaaaagaccctttcctctgatccaaatgtgagaatctgttgctttctctttgttgccactgtaaca tttattagaagaacaaagtgtgtgtgttaagagtgtgtttgcttgtaatgaactgagtgagatgcaatcgttgaatcagttttgggccttaat aaagggtttaggaagctgcagcgagatgattgtttttggtcgatcatctttgaaaatgtgtttgtttgagtaatttttctagggttgagttgatt acactaagaaacactttttgattttctattacacctatagacacttcttacatgtgacacactttgttgttggcaagcaacagattgtggacaa ttttgcctttaatggaaaggacacagttgtggatgggtgatttgtggacgattcatgtgtggttaggtgatttgtggacggatgatgtgtag atgagtgatgagtaatgtgtgaatatgtgatgttaatgtgtttatagtagataagtggacaaactctctgttttgattccataaaactatacaa caatacgtggacatggactcatgttactaaaattataccgtaaaacgtggacacggactctgtatctccaatacaaacacttggcttcttca gctcaattgataaattatctgcagttaaacttcaatcaagatgagaaagagatgatattgtgaatatgarscggagagagaaatcgaaga agcgtttaccttttgtcggagagtaatgaattc BnEPSPS5 (SEQ ID No.2) gcatgcagatcttaaaggctcttttccagtc BnFPSPS3 (SEQ ID No.3) gaattcattactctccgacaaaaggtaaacgc BnF1 (SEQ ID No.4) gcgcaatctagcagaatctg BnF2 (SEQ ID No.5) tccttcttgccgctctatct BnF3 (SEQ ID No.6) gcgttgaagaagctggggct BnF4 (SEQ ID No.7) acctataggagatttggttg BnF5 (SEQ ID No.8) actaagtgaaacattagcct BnF6 (SEQ ID No.9) gttccatatgttgaaatgac BnF7 (SEQ ID No.10) tccactctgaatcatcaaat BnF8 (SEQ ID No.11) gtaagaatctaagctcattc BnF9 (SEQ ID No.12) tcatggttgcttaaactcta BnF10 (SEQ ID No.13) cagcttgtgctgatgttcca BnF11 (SEQ ID No.14) cgatcatctttgaaaatgtg BnF12 (SEQ ID No.15) ctctctgttttgattccata BnXho (SEQ ID No.16) cgcatcagcctcgagcttcttcgtg BnMUTBot (SEQ ID No.17) ggtgagtgaacgcatggctattcctgcat BnMutTop (SEQ ID No.18) atgcaggaatagccatgcgttcactcacc BnNde (SEQ ID No.19) catttcaacatatggaacagatatc BnRB SEP (SEQ ID No.20) cccgggatattggaagttaaaggaaaagagagaaagagaaatctttctgtctaagtgtaattaaccatggcgcaatctagcagaatctg c Brasr12 (SEQ ID No.21) ggacgtggaaacagaagctg Bras r11 (SEQ ID No.22) tctcaaaccgaaagatgcag Bnapus start rev (SEQ ID No.23) ggttgaagcacaatctctgaagcttccatgg Genome walker 1 (SEQ ID No.24) gatcttgggtcattttaatgggccttctaac with the AP1 primer Genome walker 2 (SEQ ID No.25) aaataaacccattaaccactaatgaaaaagggat with the AP2 primer caMV343 (SEQ ID No.26) gcggagctcgagacttttcaacaaaggg caMY46c (SEQ ID No.27) atcccgggaagcatgcgaaggatagtgggattgtg BnGUSXma (SEQ ID No.28) cgcccgggattgaatttbaaagc FMV enhancer (SEQ ID No.29) tctagagcagctggcttgtggggaccagacaaaaaaggaatggtgcagaattgttaggcgcacctaccaaaagcatctttgcctttatt gcaaagataaagcagattcctctagtacaagtggggaacaaaataacgtggaaaagagctgtcctgacagcccactcactaatgcgta tgacgaacgcagtgacgaccacaaaagagctc caMV35S enhancer (SEQ ID No.30) tgagacttttcaacaaagggtaatatccggaaacctcctcggattccattgcccagctatctgtcactttattgtgaagatagtggaaaag gaaggtggctcctacaaatgccatcattgcgataaaggaaaggccatcgttgaagatgcctctgccgacagtggtcccaaagatgga cccccacccacgaggagcatcgtggaaaaagaagacgttccaaccacgtcilcaaagcaagtggattgatgtgatatctccactgacg taagggatgacgcacaatcccactatccttcgcaagacccttc Soyabean genomic DNA encoding an EPSPS (SEQ ID No. 31) aaaaaataccttttagtaaaataagagcgtragatcaatcagacgttttctctttgggacttctcattcttaattgaattgacaataactaaagt gaaactaaggctaaaatcaactcgcctagtcaagctcgtccacaaaaataggtttttgaaagtttaccatgtcagtttcttactaagtaaaa aaggatcatttgtaaggtccaacgccttaaaatgatcacccttcaaagtaaaagaatcacttgtttcacgcataagtaagaactacgtagg tctgatttcctctccaaaggagggtacgtaggagcaaaagccccgcttttgtcgaccttaaaaaataaaaagaaacaaaagttaaggta acacaatttccacaattctagaaataaggttgttgtctttcgagacaaacgtaagaggtgctaataccttcctcaaacgtaaatacaactcc cgaacttagaattttcattttgaccggtttccttcggttttcccgacgttttccacaaataaacgttggtggcgactccgcgcatctttcctcct ttggaaagcgcacccatgagcctcgccctcgctcgcccgcgaagggcacgttgcgacactaggttaataagaagtttagtccacatat ctatggacctcttaaggtgattatcaaagtggaagtggtgacctacatgttggccctaccagcttattcgtatatuacccccatcaaccat gtatctcagctgaaacatgctatcaatccaaatgttatcagaggaacatgagctgcatgttcaaccagaagtagttctagtcttaatacaa atgtcaaatggcacaagtgagattttgaatttctgatgttgtaaaaatctcaggacatgaatactattgggaagcaattattcatacttcacc aatccaaactgacccaaaattctcaaatcacatgaaagcaaaaatgcatataacacgaagaataagaagaagaggaactaacctggg gtttcgatgattaaagcgttgttgttgatgatgaaaacgatgattatggagagaaattgttgttgaatggtgaaattgttatagaaagagaa cgaagatagagaaaaagatatatagatttttcaaggctcaaaccctaaaatcaccatgagagagaacaaagattgagaaacctacaac cactatgagagagaatgagcagaacagaagcgtgagatagagaacgagagttaaggtgcgagaggacacgaagaacaaaaggtg tgagagaaagaacaaaggagcctacggtgtgagatgagagaatttgaaattcttaccatttaggtggaatttcaattctacaattttattct attaaaattattttaaaaaatgatgtcattttaaattctttaaaatctcatatccaacaactgaattatgatagaggtatttcaaattcacttaaaa aaattatcttatttaaataccccatccaaacatagcgaaatgttcatgagaaggatcaagtggtttggaaacatagtactaatggtgtttata cagttcatggaatccttgatagataatttaaaggttgctggaaattggatgaaggtgtggagattaaatattcttccaaaaataaagcgtttt atttggagagtgttgtgtggttgtctcccctgtaggcaaaagcttcgatgtaaaggagttcaatgtccaataacctatgctttctatccctcg attattgaaaatgaatgacacattttatttggttgaaatcaagaaataagcatgtggcaagcaacgggtatttgacaattcatagaacaaaa ggtgaatgcagcaaaagaattaatgaactccttttcgatctacttggatcactacatggagatattatcaacaaatttgatgttactttatgg agcagttggaattcttggaatgacaagatatgaaatgaacataccaaccctcctcttgtttctgtcggtttctatgcagtattttgttga~tg gcaaagtgcaaggtaatatgctcctcaacatcaattaacaaatgttcatgacatctcttaccagctccaacttggggacgtttgacaaaca ccaccgtcaagtttccttaaatgcaacattaatgttgctcatttcaaggaggagaatagttttggtgtcggcatgatactccatcaaggaag attcgtcaaagctcactcacgttttcgacatgggtcgacatgggltacctgacccaaaggctgaggcttaggcttgggtttgcttcaagta ttgatctgggcccagactattggtttacataatatcatttttgaaaacctaacatctaaaactcaaggttgtttagaggtgcgccattccaaa ataagattatcctatttgtgcatgaatgcgaccaactatctcctgtttcagcattataaagtataaacaacaaacttctttaatcaagggacta aaagatattggacatacaagctaaaagtgatagaatttgagaaaacaaatattgacaacaatattcaagaggacactaaaacataattct caaattttttttgtttatttaaaataaagtggttcattaggtagctcttgaaaaaaaaaagtgattaacatgctagtacatgttaaaaaaagtga ataatattctattataagtaaagaggaataatttatcgatgtctcattttgagatagttcaccgaagccaatttttttacttttttctcttcaatca tgttactaaatataaatttcatggtatactcaggacggttataacggaaatcaaataaataataaaatagaataatattaatttgcagtaaaa tacagatttttctctattaactaattaattaaaaattatccttattttaaggaaattaaaaattatcatatatatataagttttaaattaattatcttata tatgtaccaaaaagttttaaagcaattattataaaaattaataaatttatcatataaaataatttataattaaattttaaattatcaattcattaaatt aaattatttaaaatttttgaatgataatataataattttatcctctactaagtcccaacgtttcctattttattccadtttagcaataaattttgtcat aaacacttataacaaaaaaagtaagtaaaaaataaaaaaaagtttttcaataaagtataaactaatttgtataaacttttagaaaaaataaag aacaatgatttgcaattagatgataatataaaattattttacacactacatgtattaaactcaaacttttatatattagtttttctaaaaactaatttt taactcaaaaaaaatgttacttataattttcttatcttctttttttataagtattttttaagaaatttattgaaacatgaccatgcttgggtcaataat actactctcttagacaccaaacaacccttcccaaactataatctaatccaaaagccatcattcattttccttggtaggtaaagttccaagacc ttcaccaactttttcactcaattgttttggtgtaagcaattcgacatgtgttagtgttagttggcaaccaaaaatccctttatgtgactcaatcc aacaaccactcacaccaccaacccccataaccatttctcacaatacccttcatttacacattatcatcaccaaaaataaataaaaaaaacc taactcaaaaaaaatgttacttataattttcttatcttcttttttataagtattttttaagaaatttattgaaacatgaccatgcttgggtcaataat actactctcttagacaccaaacaacccttcccaaactataatctaatccaaaagccatcattcattttccttggtaggtaaagttccaagacc caagtgagcagagtgcacaatcttgctcaaagcactcaaatttttggccattcttccaactccaacaaactcaaatcggtgaattcggtttc attgaggccacgcctttggggggcctcaaaatctcgcatcccgatgcataaaaatggaagctttatgggaaattttaatgtggggaagg gaaattccggcgtgtttaaggtttctgcatcggtcgccgccgcagagaagccgtcaacgtcgccggagatcgtgttggaacccatcaa agacttctcgggtaccatcacattgccagggtccaagtctctgtccaatcgaattttgcttcttgctgctctctctgaggtgaagtttatttatt aagcatcatgtcccatgaaagaaatggacacgaaattaagtggcttatgatgtgaaatgaggatagaaatgtgtgtagggtttlttaatgg gtagcaataagcatattcaatatctggattgatttggacgtttctgtataaaggagtatgctagcaatgtgttaatgtatggcttgctaaaata ctcctaaaaatcaagtgggagtagtatacatatctacagcaaatgtattaggtgaggcatttggcttctctattgtaaggaacaaataatat cagttaatgtgaaaatcaatggttgatattccaatacattcatgatgtgttatttatatgtacctaatattgactgttgtttttctccgcaatgacc aagattatttattttatcctctaaagtgactaattgagttgcttactttagagaagttggacccattaggtgagagcgtggggggaactaate ttgaatatacaatctgagtcttgattatccaagtatggttgtatgaacaatgttagctctagaagataaaccctcccccaaaacacatlatta tctgtttttttttagggaacaactgttgtagacaacttgttgtatagtgaggatattcattacatgcttggtgcattaaggacccttggactgc gtgtggaagatgacaaaacaaccaaacaagcaattgttgaaggctgtgggggattgtttcccactagtaaggaatctaaagatgaaatc aatttattccttggaaatgctggtactgcaatgcgtcctttgacagcagctgtggttgctgcaggtggaaatgcaaggtctgttttttttttttt gttcagcataatctttgaattgttcctcgtataactaatcacaacagagtacgtgttcttottcctgttataatctaaaaatctcatccagattag ctgagaaatgcacctgagggtgttcctcatgatctacttcaacctctgttattattagattttctatcatgattactggtttgagtctctaagtag accatcttgatgttcaaaatatttcagctacgtacttgatggggtgccccgaatgagagagaggccaattggggatttggttgctggtctt aagcaacttggtgcagatgttgattgctttcttggcacaaactgtccacctgttcgtgtaaatgggaagggaggacttcctggcggaaag gtatggtttggattcatttagaataaggtggagtaactttcctggatcaaaattctaatttaagaagcctccctgttttcctctctttagaataa gactaagggtaggtttaggagttgggttttggagagaaatggaagggagagcaatttttttcttcttctaataaatattctttaatttgataca aatatttgtcctccattccctttcccttcaaaacctcagttccaaatataccgtagttgaattatattttggaaggcctattggttggagactttt ccttttcagagattatccctcacctttattatagcctttctatttttaaacttcatatagacgccattcttgttttaaaaaacactaagttttctttta gttataccttcccctccttattctctccaaagtaaatattgtagcaagtgttggttgatccattgtgaatcttattatcctatttaacatgcaggt gaaactgtctggatcagttagcagtcaatacttgactgctttgcttatggcagctcctttagctcttggtgatgtggaaattgagattgttgat aaactgatttctgttccatatgttgaaatgactctgaagttgatggagcgttttggagtttctgtggaacacagtggtaattgggataggttc tggtccatggaggtcaaaagtacaagtaggtttctatgttttagtgttacatcacttttagtatccaaaatgcaatgaatlttaaaactcatgtt tcctattaggtctcctggcaatgcttttgttgaaggtgatgcttcaagtgccagttatttactagctggtgcagcaattactggtgggactat cactgttaatggctgtggcacaagcagtttacaggtattcatgaatgacactatcttctattatcttttattttatagcttacactatcattcctaa ttcaacccccttcttttctctttcccctcactcccaaaatagagcttatcattgtatccttaatagctcttttatgtgctgtttcatctcttgagcag atttcattaagagtgataaaattacattgtcaagtaaagcaagttagcgtatcagataatgatgcttcgattgcagaattggtgaaagcttg cacaattcattagcttagtgacaattgtgatgtagatagccataatcttccatgcaacttattatgctttttgtctaaaacttcttttgcacttaaa catgaattagagagttaggatgaacaatagtaacagacacaaagcttatttctagaccacccagtggtgaagacgaagcagcatgagt gagattaatggcagcatctgattgaagcttcttttggtattattggagatgaaatcttgagccaaattagggcttttgcctcctcaatagcca ttggttcaaaattgctttcaataaaatgattacagaatcaaattcttaagaaagaccttcaagaacaacatcaagatgtttcctgtgcaaaac aggctcacctacaaaagagtgtctacaagcacctttacacttgcaaaaaattccttaactgaacaattgccaagagtcatgttgcaaactt gagattggagttgattagatttggtgtgtgtgagattctggaaatgagcatgaagttttttgcaaagctcataaaatgaatgcagccaaga atcctagataggattgaatttgagagagaggcttgaagtcaagataaccgcaactgatcttgetgttcccatgctgcataggactcgttg attctaccaagataacaatcttctgtggtgagaatatgagtgggaattgtcaggcaacaaagaaaatgaaggctatgagcctttgttaag gtgcagagagaaaacagaaaatgaagaacttgtgtattgaaggaattgaaaagccaattacaattgtgttgcagagagatatttatagtt ctgaagtgtataactaactaaacagaatgctaccaacctagaggcagttgagaattgctcccttattacaatactctcacagccttgatgat aggcttgatttgctgccaccgaagaagaacattattgttggagagtttttcagtgattgcatcagagaaagttacaagtgtgattggagat gaaggacttgcggtcgtcgaaggttaagtgttaagtggtggaatgtgtatcggaggtggttgcctagcccaagaagctggttgcagtg gaagcggatgcggcagaagccatgggttcagatcagaactatgttctagataccatattagggttagctttcaagagaaaacttatgaa actgaactgtaaactgttgtattattgattagctgatctagtagtgatggaagcttgcttgcgaagcttctatggaggctggatcattgagct tcaatgaggtccttcaatggtgatttttcaccatggagatgcagcggaagataaatgaagaggtgagaggaggcgtcatccactagga aataaactatggaagaaggagcttcaccaccaagagagtgtcttggataagaagcttagagaggaagcttcaatggaggaatagaaa gagagagggggaacaaaaaattgaaggaggaaaagagggagagaagttgaactttgaagtgtgtctcacaagactcattcattaaag ttacaacaagtgttacacatgcttctatttatagtctaggtaacttccttgagaagctagaacttaactacacacacctctctaataactaaga taacctccttgagaaatttccttgagaagcttccttaagaagattcctagagaagctaaagcttagttacacacacctctctaataactaagt tcacctccttgagatgagaagctagagccttagctacacacacccttataatagctaaactcactctattccaaaatacatgaaaatacaa aaaagttcctactacaaagattactcaaaatgtcctgaaatacaagactaaaactctatactactagaatggtcaaaatacaaggtccaaa agaaggaaaaacctattctaatatttacaaagagagtggacccaaccttagtccatgggctcagaaatctaccctgaggttcatgggaat cctagggtcttctttagtagctctagtccaattttcttggagtcttctatccaatatccttgggggtaggattgcatcatgtagtacaagagag gggaatatatatacagttgtaagttgtaactacctaatcaaacccaactgactcaccatacacagaaaaacaatgtacaaaggataatag aaaaactgaaactgagatatactcattacatagaagaattacatgatgaatctgaaaattttaattgggaaactgaggac~taacaagg ctttcagagttcattttgacaataggtaaattatggacttcaacttagacctcaagggtatgcttgggagtggggttttagaggaaaaggg gaaggagggaaattttttaattctagtaaatattctctattttgattaatttttaaaataaaacaaataaacttatagattagcattcacttaatgt cctgatcttttatttgtttcatgaagttttttatagcctttctgtttctgttaaaagaaattggagggtgttcataatctatatgcccatatatatgta tttttttacctgtactataactttccaaacaaatagtagaaaatgtttcaaatattccccagaactgtttcagtgaacaaagttcaagccagaa aaaaagcaagcagaggctaaagaagtatatcttattgtgaagagtaatctcaattggttaattatcgaattgtatcattttacaatagaaaat tagaagtgggttgattagtttatacgaacaattatttaaatagggttgatggtgtggttaattactgatcatatgttaagactatgagtcgatg accagcctcagtgcagtcattttaagttccattattttttaattgtgcttatgtttaactttgtccttcttttaaagggagatgtaaaatttgctgaa gttcttgaaaagatgggagctaaggttacatggtcagagaacagtgtcactgtttctggaccaccacgagatttttctggtcgaatl.agtct tgcgaggcattgatgtcaatatgaacaagatgccagatgttgccatgacacttgctgttgttgcactatttgctaatggtcccactgctata agagatggtatggtttagctgtttgtttttgctcaagagcttgttttcacatatttgtggtcaagagcggtttagctgtttttttttttaaattgtgg ttaatgaaattattataattatactaatattgaaattggatcactaaccatgtgaaatgcttgaatttttagcttgaaaacttettttgtggatgatt tttcttttatctatgtagtgtggggcatctatgttgttcctttaagctttgtgtcatagttgtacaacctggtctgtgggctggtccagtt cit act catgactgtcttttgcagcaaactggttaaacttgggtgacctgttgacccacccagattggcctgttcttttttaaataaaactccaaaagg ctacttataagatttcaacatgatacttgaatgaccacccttactttaaaggtcattatgccatcagaccccttgattctctgttcagttatgttc ttattcttattattttttaatttatattattatccaacgatctgatctttgtacatgatgctggacaatcatcaaagctagtttggttacatcatataa aatactatttcaatgactgggccttattattttctggtttgggttatacaactgtcctttgatgtacttttgaatgcttcaatagtatttttcataatc atggaaggcactagagtgcagtgcatattgcacaaggttctttaatggcatcttgaatttgttagaacatggagttatgatatacaaccatt cctatgtcttcatctaatagctaaagcttttggcgtagttggttaacatggtattggaatcttattttaaaggtccatcttattcgcaagtacaa ggcaggtggacctgcgcattattcacgtgccaggctcaaagggattttgtatgagggggaatttttggaatataatatatagaatcattca tgtggttcacctatcatgtgtcaactcaagtttttgtcctagttgtattattgcagtgtctaaactaggcatgatcttctgtggaaggaaattta acctaaggaacttgaatgcttcttgttctgagatctttattttttttctccaatctttttaatacttgaaaggttttagttgtatctataaagggtgc agaattagggggtcagcttttctgttgtaagcgtgaattaagtgcattttatgttgttccctattttatacatttgaactatcaa.ccatatcattta gcaaacttctttgttgctcagattcccatttattcttgtttcctctattttttagtggcaagttggagagttaaagagactgagaggatgatagc aatctgcacagaactcagaaaggtcttgctaattcctttatggtttctatattactggactttttacatctcactgacctactactgtcttggtat ttcagctaggagcaacagttgaagaaggtcctgattactgtgtgattactccacctgagaaattgaatgtcacagctatagacacatatga tgaccacagaatggccatggcattctctcttgctgcttgtggggatgttccagtaaccatcaaggatcctggttgcaccaggaagacatt tcctgactactttgaagtccttgagaggttaacaaagcactaagcattttgtacattgagtagggaagagagagagatatatataaatact cacaaagcagtgagtatatggcttgcttttgtttctaaacattcctttataaggacttgagataatttgtattgtttaaaagagccattggttct gttgtatcaaagtaatttaattttcagtaccgacttggctctactcatatgtggtggtgtacattgcatctttgcatttgattccatatctattgg gatgggaccatacattttttgtttattatttaagtcaaacatatcagataatatgtggtgaccagaaaagtgtctagcaatcaaatgggtctgt gattgcatgtttgagttcaggacatttattaatgagtgacagaattttaaaaagctcgccaataggagttgccacatctgatcgagtcttctg taaacactaactgtaacttgagtttgataatcagattccccccgttggtaggtaatatgtaaatttcactatagattcttactgaggatgatgg tcttgacttcgaagtggtgagtgtaattctctaatctaaactttatatatatataaaaaaagaatgttaaaaaacttgagtgacatacagcaaat agcaatgaaagcatgaccatggccttggggggccaaatggccatgtaccacttttccacctacttgagagccatggtcctgaatgaggt ccttttgtttcattttttttacaataaagaaagttcatattcttggcaatagcaaggcaaatcatttgtggaagtcacatgaaattcaccatagg cttcattgttcaaatcctttagtcactaaggcagggcctatgtaagaattttgactactcttgtaaatgctgtgcggtaaagactacgggaa aatataaattattgcatatotagaggtgaggttcatctccgatccatttctccaagtaataaaaatatatataaattattaatatggtatgata tggttatttgtcctttaaatatgcgattataggttcaatctttggttaatctatcaaatgcatctcaatattttgagagaatagtttttagctcttga ctgagagatacttgagttaaaaaatgtatttataaactattgtctattgaattttttattttttttgtaacaccacatgtgagtattttactaaatcc atgttacaatgtactgaatgttttacaatacagtctggtttgataataaaatatgcacaaagtccagcttatgtaactctttcaattcatggaaa atgatgatatgcgaattgaaagaaagaaaaccataatgtaagtgtattttttttttctttctcttctttaatattactcaatatcagattgcacatg ggaagggtactggctcatgtgggatattaatttttatcccttacctaaaaagagagaaagagaaaataactatttaaaaagagtaccacc accacctttttcgcttttaagttttgttetgttttcactactctttcatgcgttgtttgttggcttccgatagtgacgaatatgataatgattttacgt tgagaaaaaaaatgtgccatgtaaattccagagattgaaattttagcttcaaattaatatttattttattatcttttcaaattggttgcatgtgaa agaatttgaagttcttcaacaaggaaataaacacttcaatgctcaatccttagagtcagtcactagatcccaaaagaatgtgatgtttacac acattagtatatatatatatataaacacagcttatattatattaatgagtgatgcgcgaggacggtggtgacactacatggccaaaacaag aaatgtaatttaatttttttttctttaagtattactctatccttgaatattagtcttaaatcttcaaagaccttgcgaacgaagcaatcttgtcctga tcctgtgattgttctacactagtccttacgtgtacctaagcacatgatactttgctgccctaacataaattgtaccataaggattcttgggga gatgcttttgccttcattttcaagtttgtttacactttcaagtcgttttttcaatgcattctctttcctttctgggaccccttgtctttaacacgcgc gcacacaaaaactagtagacaataattagtactacttgggttccattaaattgtaactacatatacatgtgttttttttttcttggatcaactgc atatacatatgttttatgagtttcattgaatttatatttacacaaacagttattaaaacataatgtagagccttgtcattaacctgatgttaggatt ccgttcaaaagagagacgacaaggataatactaatactagtagattccacgcattcaaccctagttagtttagctatgacaaattaagcat ggtaagaaaaggggaggagaaaagtaagaatgaaaacatataacaaattgtgattgaacttttccatgacgtaatgaaaacattaatttt aagataagcttcaactcctaagaagagatatgtcaaagaaacttaggattttttctctatttataacggtaaattactcatccttttaaatgatt aatttgcgttgttgaattcgttgtaaagggaaaatcaagaagtctcttcacgggaaagttatatcaaagtatcatatactagacttcatggct agcttttactttgattataagtaatgcatgcaattaatgggcaaataaattatttgaaaccaactaaagtacaaataattttcctccaaaacct ctcaagttcgcattgaaattaaataaaccaatgcatattaaggcgtaaatctaaaccatgtttgtttcatcttgtattgtatatcatagtattaat aaggtactttgaatttagttgttattgaccgttaaatttaggggtgagttgttttactatctcttactcaattgcttttattcaacgcaaattctagt aggattttcagcccaaattaaaagaagttttacggtttgattctctacaaacttgaattgagatttctaatttcagaaatcaataattgcggtct taattaactctataatcaaaccttttaacccaatctttttctcaattctctgaattaagacaatcaaaatttaaactcacacgaatctcacacgc cttcccacggtagagaaatatagggagtcccttaatagcaaaagcctcaaaattcagaaaatctcatccattgcatttgcacattcaacaa accacccattattatgttcccttaataaatctcacacttaaaaaccctcctcacccataattaacccaaaaggaagtttcctccacacaaaa aatatccttaaacaaagagcctctataaatctattttaaaaaaacccccaaatttaagga Soyabean geriomic DNA encoding an EPSPS (SEQ ID No. 32) aaaagtctgaatgaagtgaagttgttgtgttagggggatgctgaatttgattttaatttaatttaaataaattacctgtgtaaaggatttttgta ccgccttttaatcacaaattgtcgtgtatcgaaagtttgttgaattttatagtaactatcttggaggttatacctagtaggatttctgattagtta accatgtaaatttttttaatgggtttgtgtttgttttaactgatgttgtttttgatatgtacgtggtaagtgtgatgagtttgtgcatatcttgatca aagactgaagtgaagttgttgtgtttggggggttgactcttttaggaagaggatttgagggaatttcgccaatgggggagcagaactcc gggacaccctgagaattttgagactccgggaattgaagttacaacaggtttgatatgagttagagtttgtataatagaatagtaattcttttt attttttatttttattgtttatttatccattattgctatttttgtaggtcctcttggtcaggggattgccaatgctgttggtttggeccttgcagagaa gcacttggctgcaagatacaacaagcctgacaatgagattgttgaccattacacgtaaaaaataactaaatcatacacaacttgcaagact ttagttgttggtgttttgctaatggcgtttgttttatgcaggtatgctattctgggtgatggttgtcaaatggagggaattgcaaatgaagcat gctcacttgctggccactggggactggggaagctgatagcattttatgatgacaatcatatttctattgatggtaacacagagattgcgtt caccgagagtgttgatagtcgttttgagggacttgggtggcatgttatttgggtaaagaatggaaataatggctatgatgatattcgtgct gccattaaggaagcaaaagctgtcaaagacaaacccacattaatcaaggttagtttactaattgtggcaatgatatgcatagatttctggc ttgtagttaccataacaatcataatctgtcatgatttatagggattcttttaaactaaggttataaacatgatatgttactaaagactgcattgc attgtagtacctcatttgagaaactggaagttataggtgggaaatcaaaatagtaaattatgggtcagtttattaagtgtagctggtttgtctt ttgctaactctatcatttcacaggtcacaacaaccattggttatggttctcctaacaaggetaactcctacagtgtgcatggaagtgcactg ggtgccaaagaagttgatgccaccaggcagaaccttggatggtcacatgagccattccacgtgcctgaggatgtcaaaaagtatggat gatgggtttagagatttcttttttcctgtgacactgctgatgtttataatgatactgaataagaattgcttgtctgtccccaggcattggagtc gccacacccctgagggtgctgcacttgaagctgagtggaatgctaagtttgctgagtatgaaaagaaatacaaggaggaagctgcag aattgaaatctattatcaatggtgaattccctgctggttgggagaaagcacttccggtgagtaaattctaaactcacaggtttttcttacatgt ttgtaacttttcaaggtttggattacatactatccaaagttgatcatgatttcagtttgatttggtagtatggggcttcaaaaagttattccaaat attaaaacctggcttccaatttgatttcagacatacactccagagagcccagcggatgccaccagaaacctgtctcaaacaaaccttaat gcccttgcaaaggttcttcccggtctgcttggtggcagtgcagatcttgcttcttccaacatgaccttgctcaaaatgttcggggacttcca aaaggatactccagcagagcgtaatgttagattcggtgttagagaacacggaatgggagctatctgcaacggcattgctcttcacagcc ctggactgattccatattgtgcaaccttctttgtattcactgactacatgagaggtgccataaggctttctgcgctgtctgaggctggggtta tttatgtcatgacccatgattcaataggacttggagaagatgggccaacccaccagcctattgagcacctagcaagcttccgggcaatg ccaaacattttgatgcttcgtcctgccgacggtaacSgaaacagccSgagcatacaaagtggccgtgctcaacaggaaagagaccct ccattcttgccctatccaggcaaaaactgccccagcttcccggaactthcattgaaggagttgaaaagggtggttacaccatttcggga caactccactggcaacaagcctgatgtcattttgatcggaactggttcggaattggaaatcgctgccaaagctgctgatgacctaagga aggaagggaaggctgttagagttgtttcccttgtttcttggggaactttttgatgagcaatcagaagcStacaaggagagtgtt~ccctg ctgctgtttcagccagagttagcattgaggcaggatcaacatttgggtgggagaaaattgttggagcaaagggaaaagcaataggcat tgatcgttttggagctagtgotccagctggaagaatatacaaagaatttggtatcactaaggaagctgttgttgctgcagctaaagagctt atctagaacttttgatttttttttgccttciggttttggttgagagcattccatgtcatgaataagaaaaaggttaaatatccttcgattgggaat ttgggattctaagtgaagaagcaacatagatcaaagaattttgtgaacttgtaataactatttgacaatttagttttgcactgccacatggtta aattcaatgtttgatcatateaaccatagatgctagtttatactacttgtataatttgtttcacttgcagattcactcttagcatttgagtgtttgg atggccgtgttttgttcattaagaaatgttgacatggatagtttgttgcatggtaaattggtgattaatacctttttaagcttcttttggcaagtt gttaaaaagtgttttgttttaatctctagttaatctaaaaatgcctacttattttattttgactttcaaaacttgtctatatgccgagtataaaaaaa actctatataagttccttatggaaaaaggacctacaaataatttaaaaatgctgaatttgttaggaagtttgacaactttagacattaat aattgtttttttttcatatatataattgactttcaaaacttgtctatatattataaattcgttatggaaagggcgaccacacgtaaaacgtaacat gccaatctctccctagtgaactgttattctcattcagtttttgtaagttcaccttcaaattttcaattttttttttgacaaaaatatctttgatggaac acgttaggggtgtaaattcaccattcatcatttcattcattatacacaatagtctttcataatccaatgaaaacttgtttttgttgttatttttttctg aaaaatctttataaaataaataaaaacatttttttgttataaatttcagttgaaatacataaccattaattctacagagtgttaatgttgatgtaaa ataaaaaaatattggatatcaaacttaatgaacagaacaaaaattacaaaattgtacaatttaaatgataaaaaaccaaattcacaaaaata aaaattaaggacgaaatttgagaaatgataattaaaaacgattaaaaatataattaaactaaaatttattatgtaattctttaatatatatatata tatatatatatatatatatatatatatatatataataaaagttttacattataattttgaaatgaagtatttgataaacgaacaacccacccttggg gttggtgagagtgaaacggagaacagtgtctccctcacttggtcttctgagtcgagtcctattcatcaccaacccactcgtcaaaattgtt gtatgctatgtaaccattttgttttttaataaataaaagtgttttgttctgctatgcactccccatcaaataccatttactttttttttgtcttctatca attctatttagttcctagttgctacaacttccagctggtgaaaatagtcaacagagactacaatattctaataaaatagaataacaaaatc aaaaatttctacaattatagaaaaagtttagttttgtagattgttaacataaagatttttcctattaactaattaattaaaagtcatcttatatataa gttttaaagtaattatcttatatatgtacccaaaagttttaaagcaattattataaaaaagtaaaattttatcatatacaataatctataattacat attttattccacttttaccaataaatttcctcataaacacttataagaaaaaaagtaagtaaagaataaaataagcttttctataaactataaac ttttttaagaaatttgttcaaacatatttttatgacatgtcaatgcttgagagatataaggtgagttaaatcataaatgattaaagaaaaataaa agaagaaaaagataattaatttaattttttattaacattctaacaaattaacattatataaataaaaataatatttcaataattggatcaataatac tattgttcttaaacaccaaaccaaccttcctaaagtcctaatctaatccaaaagccatcattcattttccttggtaggtaaagttccaaaacct ttaccaaccttttcactcaattattttggtgtaagcaattcgacatgtgttagtgttagttggcaaccaaaaacccctttatgtgactcactcaa tccaacaacctctcacaccaccaacccccccatactcataaggccaaaaccatttctcacaaaacccttcattacacacattattatcatt atcacacacacaaaaaacctctcatttcaaagagagagagagatttcacagaccaaattgcagaggacgacaaagttcacaacttcaa ggaaaatcgaaatggcccaagtgagcagagtgcacaatcttgctcaaagcactcaaattttyggycattcttccaayyccaacaaacy caaatcggygaattcggtttcattgaggccacgcctttggggkscctcaaaatctcgcatcyygrtgrnayaaaamtggaagcyttat gggaaattttaatgyggggaagggaaattccggcrtgtttaaggtttctgcatcsgtcgccgccgccgcagagaagccgtcaacgtcg ccggagatcgtgttggaacccatcatlagacttctcgggtaccatcacattgccagggtcgaagtctctgtccaatcgaattttgcttcttg ctgctctctctgaggtaaagtttatttatttatttatttctgtatccaaaaatgtaaattgttagtttgttaatttttgttagcagtgagagtcgaact acttggcttctttcttagtcatccaaccaaccttatatctccaaaatttatttattggttttttttggggttatgtggttaggaataggagtttgatg cgtggagtggattttgaatatttgattttttttttttttgtattattcagtgaaaatgaagcatcttgtcccatgaaagaaatggacacgaaatta agtggcgtatgatttagaatgatgatagaaatgtgtataggtggttttaatgtgtagcaataagcatattcaatatctggattgatttggacg tttctgtataaaggagtatgctagcaatgtgttaataatgtcttgttaaaagtatggatggctaaaataatcataaaaatcgagtgggagta gtatacatatctacaggaaatgtattaggtgaggcatttggcttctctattgcgagtaaggaacaagtaatctcagttaatgtgaaaatcaa tggttgatattccaatacattcatgatgtgttatttacgggaacgcaatattgactgttgattttatctgcagctgagattatatactatatcctt ccaaagaaatctttgactcttgattatccaagtatggttgtattaccaattttagctctaga.agataatccctcccccaaaacacaaattaga tttttattcttatttagggaacaactgttgtagacaacttgytgtagagggaggatattcattacatgcttggtgcattaaggacccttggact gcgtgtggaagaygacmaaacaaccaaacaagcaattgtkgaaggctgtgggggattgtttcccactaktaargaatctaaagatga aatcaatttattccttggaaatgctggtactgcratgcgtcctttgacagcagctgtrgttgctgcaggtggaaatgcaaggtctgttttttgt tttgtttgttcatcatgatctctgaattgttcctcgtataactaatcacatcagactatgtgttcttcctccatcctgttataatctaaaaatctcat ccagattagtcatccttctttaaatgaacctttaattatatctatgtatttatttaacatgtaaattagcttgtcaagtcaaagtctagcatataga tatactgattacactctgaggaatgcacctgagggtcttaatcatgatctatttcaaccttgccactttcttcttttattattagatcacctatcat gattactggtttgagtctctaaatagaccatcttgatgttcaaaatatttcagctacgtacttgatggrgtgccccgaatgagagagaggcc aattggggatttggttgctggtcttaagcatctyggtgcagatgttgattgctttcttggcacaaactgtccacctgttcgtgtaaatggga agggaggacttcctggcggaaaggtatggtttggatttccattagaataaggtggactaactttcctggagcaaaattctaatttataccct gtttccccctctttagaataagacactaagggtatgtttaggagttgggttttggcgagaaagggaagggagggcaattttttttctaataa cctctatttaaaaacaagatatttttcctccattccctttccctttaaaacctcagttccaaatataccgtacttgaattatattttggaaggtgta ttggttggagacctttccttttcagaggttatccctcacctttattatagcctttctactctcttaatgagttcattgtgcattgagtcattgaactt cctgtgaaaagaaattgtttacttttctttatttgttacctacatccttattcctgttttaaaaaatactaagttttcttttagttatgccttcccctcc ttattctctccaaagaaaatataatagcagaatgttggtttatccattgtgaatcttattatcctatttcacatgcaggtgaaactgtctggatca gttagcagtcaatactgactgctttgcttatggcagctcctttagctcttggygatgtggaaattgagattgttgataaactgatttctgttc catatgttgaaatgactctgaagttgatggagcgttttggagtttctgtggaacacagtggtaattgggatargttcttggtccatggaggt caaaagtacaagtaggtttctatgttttagcattacatcactttttagtatccaaaatgcaatgaaatcaaaactcatgttttctatcaggtctc ctggcaatgcttttgttgaaggtgatgcttcaagtgccagttagttmctagctggtgcagcarttactggtgggactatcactgttaatgg ctgtggcacaagcagtttacaggtattcatgcttgacactattttctattatcttttattttatggtctatactgtatcattcctaattoaaccccct tcttttctctttcccctcacttccaaaaaaatagagcttatcattgtattcttaatagctcttgtatgtcctttttcgtctcttgagcagattctacc tatttcattaacagtgataaagataaaaataaattgtcaagtaaagcaagttagcatgtcagataatgatgcttcaattgcaaaattggtgaa agcttgcacagtacattagctttggtgacaattgtgatgtagatagccataacctcccatgcaacttattatgttgtttgcttaaacttcttttg cacttaaacacggattagagagagtgaggatgaacaataataacagacacaaagcttagttttataccacccggcacccagtggtgaa gaccaagcagtatgagtgagatcaatggcagcatctgattgaagcttcttgtggtatttttggagatgaaatccgaggcgaattagggca tctggctcaacaatagccattggttcaaacttgcttttaataaaattgattacagaatcaaattcttgaggaagccttcaagaactacatcat gatgttccctgtgcaaaacaggttcaccgacaaaagagaacatctacaagttcctttacacatgccaaaaattcctcaactgaacaattg ccaagagtcatgttgcgaacttcaggttggagttgacgaaatttggtgcatgtatgattctggaaatgagcatgaagttttttcctaagctc ataaaagtgaatgcagccaagaaccctagataggattgaatcggagagaggcttgaagccaagataacagcaactgatcttgctgttc ccatgctgcgtaggactcattgattctaccaagatcacaatcttctgtggtgagaaaatgagggtgaattgtcaaccaataaagaaaatg gtgaaggctgagtcttgatgataggcttgatttgcttgcgctgaagaagaacgttattgttgtagagtttctcagtgattgtatgagagtaa gttacaggtgcgattggagatgacggacttgtggtgggaggagggtaagtgttaagtggtggaatgcgtatcagaggtggttgccca gccaaagaagctggttgcggtggaggaggtggtggtgcagtggaagccatgggttttgatgcttttgagagaaaacatacgaaactg aactgtaaacttttgtattattgattagctgatttggtagtacaagagaggaatatatatacagttttaatgtaactacctaaccaaacatgag gaactctccatacacagaaagacgtatacaaaggataacagacaaacagaaacttagatatactcatacagagaagaattacaggatg aatctgagaattttaattgggaaactgaggaaaatagcaagggtttcagaattcattttgacgataggcaaatcatggacttaacttagac ctcaagggtacgcttgggagtgggggtttttagagggaaaagggaaggagggcaaacttttaattcctaataaatattctcttttttgatttt ctatagtatgtataactattcaaataaatagtagaaaatgtttcaaatattccccagaactgtttcagtgaacaaagttcaagccagaaaaa agaagtatatcttcttgtgaagagtagtctcaagtggttaattgtcaaattgtatcattttagaatacaaaattagaagtggtttgattagtttat acgaacgattatttaaatagggttgatgatgtggttaattactgatcatatgtgaagactgtgagtcgatgaccagcccagtgcagtcattt taaattccattattttttaatttgtgcttatgttaaactttgtccttctttcaaagggagatgtaaaatttgctgaagttcttgaaaagatgggagc taaggttacatggtcagagaacagtgtcacygttwctggaccrccacragattyttctggtcraaaagtcttgcraggcattgatgtcaat atgaacaagatgccagatgttgccatgacwcttgcygttgtgcactatttgctaatggtcmmactrcyatmagagatggtatgttt agctgtttgtttgtgttcaagagcttgttttaacaaattgttttttttaattatggttaatgaaattattataattacactaatattgaaattggatca ctaaccatgtgaaatgcttgaatttttagcttgaaaacttcttttgtggacaatttttcttttatctatggattgtggggcatctatgttgttccttt aagcttcgtacaacctggtctgtgggctggtccagtccttcttactcatgacagtcttttgcagtaaactggttaaacttgggtgacctgttg acccacccagattggcctgttctttttaaataaaacttggctacttataagatttcaacatgatacttgaatgatcacccttactctaaaggcc gtttcgtttttttcctggcttgaatgctatttcaatgactgggccttattattttctggtttaggttatacaactgtcctccaattgacttttgaatg cttcaatagttttcttcttaatcatggaaggcactagagtgcatattgaatatgttagaacatggaaggcttaaatatctttttagtctttgcaat ttaacgtttttttgcttttagtccttgcaaaattataatttttttttagtcctgactaattatgtttgttttgtttttgagggcgagccctggtgcagc ggtaaagttgtgccttggtgacttgttggtcatgggttcgaatceggaaacagcctctttgcatatgcaagggtaaggctgcgtacaatat ccctcccccataccttcgcatagcgaagagcctctgggcaatggggtagaaaaagaagaatgctttagataacactttttttgttactgtt caaagcactatctaaagtgctttgaggactaaacacaaaacaaacataatttgcaaggactgaaaaacaaaaaaataattttgcaagga caaaaaaacaaaaaaaaaaaacaaaattgcaaggaccaaaaatatatttaaaccaacatgaaattatggtataaaaccattcatatgtctt catctaatagcttaagcttttgggatagttggttaacaatatggtattagagtcttatgatttttaggtggtctttgagttcaatccttgctgctc ccagttctagttaatttctttttggtccacttcaaataaaaagttgaatttaagggtaaggcagctggacctgcgcattaatcatgtgtcagg ctcaaagggcttttgtatggggggcatgtttggaatataatatagaatcattcatgtggtttcacctatcaaggacaactctagtttttgtcat acttgtattattacagtgtctaaactagacatgatctttttccggaaggaaatttaaacttaaaaggaacttagatgcttcttgttctgtgatcttt tttgctgctcagattctcctttggactatctaccatatcatttagcaaacctgttcactgctcagattctcatttattctttgtttcctctatttttca gtggcaagttggagagttaaagagactgagaggatgatagcaatctgcacagaactcagaaaggtgagtgtcttgctaattcctttatg gtttcgatattactggactttttacatctcactgacctactctgtcttggtatttcagctaggagcaacagttgaagaaggtcctgattactgt gtgattactccacctgagaaattgaatgtcacagctatagacacatatgatgaccacagaatggccatggcattctctcttgctgcugtg gggatgttccagtaaccatcaaggatcctggttgcaccaggaagacatttccygactactttgaagtccttgagaggttmacaaagca ctaagcattttgtacattgagtaggaagagagagagagataaatactcacaaaacagtgagtatatgcatggettgcttttgtttcttaaca ttcccttgtaagaacttgagataatttgtattgttggaaagagctattgattctgttgtatcaaagtaatttaatttccagtacagacttggctct attcctcatatgtggtggtgtacattgcatctttgcatttgatcccatttctattgggataggaccatacctttttttgtttattattcaagtcaaac ttagcagataatatgtggtgaccagaaaatagtctagctagcaaatagacctgtgattgcatgttlgaattcaggacttcaggacatttaat taatgagtgacaatgttaaaaagctcgccaacaggagttgacacatctgattgagtcttctattaacactaactgtaacttgagtttgattat cagattcctcctgttggtaggtaatatgtaaatttcactatatatttaccgaggttggtggtcttacttgactttgaagaggtgagtgtaattta aacttttatatcaaaaaaagattgctaaaagcttgagtggcatgcaacaaatagcaatgaaagaatgactatggccttgggaaccaaatg gccacgtaccacttttccaccaacttgagagccctggtcctggatgatgcccctttttttttttcatttctttgacaataaagaaagttcttattc ttggcaattgcaagtcgtttgtggaagtcacatgaaattcaccataggcttcattgttcaaatcctttagtcactaactaaaggctggaccta tgcaagaattttggctactcttataaatgctgtgcggcaaagactacggaaaaatataaattattgcatatctagaggtgaggttcattgct cccatccatttttccaagaactaaaatatatataaattattaatatgatattacattgaaaaataatatttttcttttaaatatgtgatcataagttta attttaagtctattcatacgaaaaaaatatttattagaaaagattaatttattaaatggatctcaatattttaagaaattaacttttagctctcaac caacagatgatttgagttaaataaaatgtatatataaactattgcatatctgctgatttttgtttgtaacaccaataagtgggcattttactaaat ccatgtgacaatgtactgaatgttttagaatacagtctggtttgataataaaacgtgcataaagtccagcttatgttaactcttaattcatgga aaatgatgatatgcgaattgaaagaaagaaaaccataatgtaagtgcagttttctctctcttttttaatattattcaatatcagattgcacatg ggaaggggtattggctcatgtgggatattagtttttgtcccttacctaaaaagagagaaagagaaaaataacaatttaaaaagagtacca ccgctaccacctttttcgcttttaaatttttgttctgttttcactactctttcatgcgttgtttgttggcttctgatagtgacgaatatgatataatga ttttatgttgggaaaaaagtgccatgtaaattctagagattgaaattttagcatcaaattatttattttatcaccttttaaaatttgttgcatgtga aagaatttgaagctctccaacaaggaaataacacttcaatccttagagtcatcctctagatcccaaaagaatgtgatgtttatacacattag ggtggtgacactatatggccaaaacaagtgtaatataattatttttttttctcaagtattactctatccttgaatattattagtcttaaatcttcaa gcaccttgtgaacgaagcaatcttgtcc EPSPS 10 reverse (SEQ ID No.33) gcacarcgigcaagigaraaigccatigccat EPSPS 4 torward (SEQ ID No.34) gcwggaacwgcmatgcgiecrytiacigc SEQ ID No. 31 with double mutation (SEQ ID No.35) aaaaaataccttttagtaaaataagagcgtragatcaatcagacgttttctctttgggacttctcattcttaattgaattgacaataactaaagt gaaactaaggctaaaatcaactcgcctagtcaagctcgtccacaaaaataggtttttgaaagttttaccatgtcagtttcttactaagtaaaa aaggatcatttgtaaggtccaacgccttaaaatgatcacccttcaaagtaaaagaatcacttgtttcacgcataagtaagaactacgtagg tctgatttcctctccaaaggagggtacgtaggagcaaaagccccgcttttgtcgaccttaaaaaataaaaagaaacaaaagttaaggta acacaatttccacaattctagaaataaggttgttgtctttcgagacaaacgtaagaggtgctaataccttcctcaaacgtaaatacaactcc cgaacttagaattttcattttgaecggtttccttcggttttcccgacgttttccacaaataaacgttggtggcgactccgcgcatctttcctcct ttggaaagcgcacccatgagcctcgccctcgctcgcccgcgaagggcacgttgcgacactaggttaataagaagtttagtccacatat ctatggacctcttaaggtgattatcaaagtggaagtggtgacctacatgttggccctaccagcttattcgtatatttacccccatcaaccat gtatctcagctgaaacatgctatcaatccaaatgttatcagaggaacatgagctgcatgttcaaccagaagtagttctagtcttaatacaa atgtcaaatggcacaagtgagattttgaatttctgatgttgtaaaaatctcaggacatgaatactattgggaagcaattattcatacttcacc aatccaaactgacccaaaattctcaaatcacatgaaagcaaaaatgcatataacacgaagaataagaagaagaggaactaacctggg gtttcgatgattaaagcgttgttgttgatgatgaaaacgatgattatggagagaaattgttgttgaatggtgaaattgttatagaaagagaa cgaagatagagaaaaagatatatagatttttcaaggctcaaaccctaaaatcaecatgagagagaacaaagattgagaaacctacaac cactatgagagagaatgagcagaacagaagcgtgagatagagaacgagagttaaggtgcgagaggacacgaagaacaaaaggtg tgagagaaagaacaaaggagcctacggtgtgagatgagagaatttgaaattcttaccatttaggtggaatttcaattctacaattttattct attaaaattattttaaaaaatgatgtcattttaaattctttaaaatctcatatccaaeaactgaattatgatagaggtatttcaaattcacttaaaa aaattatcttatttaaataccccatccaaacatagcgaaatgttcatgagaaggatcaagtggtttggaaacatagtactaatggtgtttata cagttcatggaatcettgatagataatttaaaggttgctggaaattggatgaaggtgtggagattaaatattcttcc~iaaataaagcgtttt atttggagagtgttgtgtggttgtctcccotgtaggcaaaagettcgatgtaaaggagttcaatgtccaataacctatgctttctatccctcg attattgaaaatgaatgacacattttatttggttgaaatcaagaaataagcatgtggcaagcaacgggtatttgacaattcatagaacaaaa ggtgaatgcagcaaaagaattaatgaactccttttcgatctacttggatcactacatggagatattatcaacaaatttgatgttactttatgg agcagttggaattcttggaatgacaagatatgaaatgaacataccaaccctectcttgtttctgtttcggtttctatgcagtattttgttgaatg gcaaagtgcaaggtaatatgctcctcaacatcaattaacaaatgttcatgacatctcttaccagctccaacttggggacgtttgacaaaca ccaccgtcaagtttccttaaatgcaacattaatgttgctcatttcaaggaggagaatagttttggtgtcggcatgatactccatcaaggaag attcgtcaaagctcactcacgttttcgacatgggtcgacatgggttacctgacccaaaggctgaggcttaggcttgggtttgcttcaagta ttgatctgggcccagactattggtttacataatatcatttttgaaaacctaacatctaaaactcaaggttgtttagaggtgcgccattccaaa ataagattatcctatttgtgcatgaatgcgaccaactatctcctgtttcagcattataaagtataaacaacaaacttctttaatcaagggacta aaagatattggacatacaagctaaaagtgatagaatttgagaaaacaaatattgacaacaatattcaagaggacactaaaacataattct caaattttttttgtttatttaaaataaagtggttcattaggtagctcttgaaaaaaaaaagtgattaacatgctagtacatgttaaaaaaagtga ataatattctattataagtaaagaggaataatttatcgatgtctcatttttgagatagttcaccgaagccaatttttttacttttttctcttcaatca attttattttgttaatagtgtcattgtggatggattataataattttgaaatgatttaaaatgagatatatattaataaatttaattaattcataaata tgttactaaatataaatttcatggtatactcaggacggttataacggaaatcaaataaataataaaatagaataatattaatttgcagtaaaa gtttcttattttattaccattttgttcacttctcaattaataaaataaaaatatattctacaattatagtaaaaaggtttaattttatataatgttagca tatgtaccaaaaagttttaaagcaattattataaaaattaataaatttatcatataaaataatttataattaaattttaaattatcaattcattaaatt aaacacttataacaaaaaaagtaagtaaaaaataaaaaaaagtttttcaataaagtataaactaatttgtataaacttttagaaaaaataaag aacaatgatttgcaattagatgataatataaaallattttacacactacatgtattaaactcaaacttttatatattagtttttctaaaaactaatttt actactctcttagacaccaaacaacccttcccaaactataatctaatccaaaagccatcattoattttccttggtaggtaaagttccaagacc ttcaccaactttttcactcaattgttttggtgtaagcaattcgacatgtgttagtgttagttggcaaccaaaaatccctttatgtgactcaatcc aacaaccactcacaccaccaacccccataaccatttctcacaatacccttcatttacacattatcatcaccaaaaataaataaaaaaaacc tctcatttcagagagagagagagagacttcacagaccaaagtgcagagaacaacaaagttcacaactttaaggaaaattgaaatggcc caagtgagcagagtgcacaatcttgctcaaagcactcaaatttttggccattcttccaactccaacaaactcaaatcggtgaattcggtttc attgaggccacgcctttggggggcctcaaaatctegcatcccgatgcataaaaatggaagctttatgggaaattttaatgtggggaagg gaaattccggcgtgtttaaggtttctgcatcggtcgccgccgcagagaagccgtcaacgtcgccggagatcgtgttggaacccatcaa agacttctcgggtaccatcacattgccagggtccaagtctctgtccaatcgaattttgcttcttgctgctctctctgaggtgaagtttatttatt tatttatttgtttgtttgttgttgggtgtgggaataggagtttgatgtgtagagtggattttgaatatttgatttttttttgtattattctgtgaaaatg aagcatcatgtcccatgaaagaaatggacacgaaattaagtggcttatgatgtgaaatgaggatagaaatgtgtgtagggttttttaatgg gtagcaataagcatattcaatatctggattgatttggacgtttctgtataaaggagtatgctagcaatgtgttaatgtatggcttgctaaaata ctcctaaaaatcaagtgggagtagtatacatatctacagcaaatgtattaggtgaggcatttggcttctctattgtaaggaacaaataatat cagttaatgtgaaaatcaatggttgatattccaatacattcatgatgtgttatttatatgtacctaatattgactgttgtttttctccgcaatgacc aagattatttattttatcctctaaagtgactaattgagttgcttactttagagaagttggacccattaggtgagagcgtggggggaactaatc ttgaatatacaatctgagtcttgattatccaagtatggttgtatgaacaatgttagctctagaagataaaccctcccccaaaacacaaatta gaatgacatttcaagttccatgtatgtcactttcattctattatttttacaacttttagttacttaacagatgtcttgttcagcataaattataatttat tctgtttttttttagggaacaactgttgtagacaacttgttgtatagtgaggatattcattacatgcttggtgcattaaggacccttggactgc gtgtggaagatgacaaaacaaccaaacaagcaattgttgaaggctgtgggggattgtttcccactagtaaggaatctaaagatgaaatc aatttattccttggaaatgctggtactgcaatgcgtcctttgacagcagctgtggttgctgcaggtggaaatgcaaggtctgttttttttttttt gttcagcataatctttgaattgttcctcgtataactaatcacaacagagtacgtgttcttcttcctgttataatctaaaaatctcatccagattag ctgagaaatgcacctgagggtgttcctcatgatctacttcaacctctgttattattagattttctatcatgattactggtttgagtctctaagtag accatcttgatgttcaaaatatttcagctacgtacttgatggggtgccccgaatgagagagaggccaattggggatttggttgctggtctt aagcaacttggtgcagatgttgattgctttcttggcacaaactgtccacctgttcgtgtaaatgggaagggaggacttcctggcggaaag gtatggttggatttcattlagaataaggtggagactttcctggatcaaaattctaatttaagaagcctccctgttttcctctctttagaataa gactaagggtaggtttaggagttgggttttggagagaaatggaagggagagcaatttttttcttcttctaataaatattctttaatttgataca aatatttgtcctccattccctttcccttcaaaacctcagttccaaatataccgtagttgaattatattttggaaggcctattggttggagactttt ccttttcagagattatccctcacctttattatagcctttctatttttaaacttcatatagaogccattcttgttttaaaaaacactaagttttctttta gttataccttcccctccttattctctccaaagtaaatattgtagcaagtgttggttgatccattgtgaatcttattatcctatttaacatgcaggt gaaactgtctggatcagttagcagtcaatacttgactgctttgcttatggcagctcctttagctcttggtgatgtggaaattgagattgttgat aaactgatttctgttccatatgttgaaatgactctgaagttgatggagcgttttggagtttctgtggaacacagtgg-taattgggataggttc ttggtccatggaggtcaaaagtacaagtaggtttctatgttttagtgttacatcacttttagtatccaaaatgcaatgaaattaaaactcatgtt tcctattaggtctcctggcaatgcttttgttgaaggtgatgcttcaagtgccagttatttactagctggtgcagcaattactggtgggactat cactgttaatggctgtggcacaagcagtttacaggtattcatgaatgacactatcttctattatcttttattttatagcttacactatcattcctaa ttcaacccccttcttttctctttcccctcactcccaaaatagagcttatcattgtatccttaatagctcttttatgtgctgtttcatctcttgagcag atttcattaagagtgataaaattacattgtcaagtaaagcaagttagcgtatcagataatgatgcttcgattgcagaattggtgaaagcttg cacaattcattagcttagtgacaattgtgatgtagatagccataatcttccatgcaacttattatgctttttgtctaaaacttcttttgcacttaaa catgaattagagagttaggatgaacaatagtaacagacacaaagcttatttctagaccacccagtggtgaagacgaagcagcatgagt gagattaatggcagcatctgattgaagcttcttttggtattattggagatgaaatcttgagccaaattagggcttttgcctcctcaatagcca ttggttcaaaattgctttcaataaaatgattacagaatcaaattcttaagaaagaccttcaagaacaacatcaagatgtttcctgtgcaaaac aggctcacctacaaaagagtgtctacaagcacctttacacttgcaaaaaattccttaactgaacaattgccaagagtcatgttgcaaactt gagattggagttgattagatttggtgtgtgtgagattctggaaatgagcatgaagttttttgcaaagctcataaaatgaatgcagccaaga atcctagataggattgaatttgagagagaggcttgaagtcaagataaccgcaactgatcttgctgttcccatgctgcataggactcgttg attctaccaagataacaatcttctgtggtgagaatatgagtgggaattgtcaggcaacaaagaaaatgaaggctatgagcctttgttaag gtgcagagagaaaacagaaaatgaagaacttgtgtattgaaggaattgaaaagccaattacaattgtgttgcagagagatatttatagtt ctgaagtgtataactaactaaacagaatgctaccaacctagaggcagttgagaattgctcccttattacaatactctcacagccttgatgat aggcttgatttgctgccaccgaagaagaacattattgttggagagtttttcagtgattgcatcagagaaagttacaagtgtgattggagat gaaggacttgcggtcgtcgaaggttaagtgttaagtggtggaatgtgtatcggaggtggttgcctagcccaagaagctggttgcagtg gaagcggatgcggcagaagccatgggttcagatcagaactatgttctagataccatattagggttagctttcaagagaaaacttatgaa actgaactgtaaactgttgtattattgattagctgatctagtagtgatggaagcttgcttgcgaagcttctatggaggctggatcattgagct tcaatgaggtccttcaatggtgatttttcaccatggagatgcagcggaagataaatgaagaggtgagaggaggcgtcatccactagga aataaactatggaagaaggagcttcaccaccaagagagtgtcttggataagaagcttagagaggaagcttcaatggaggaatagaaa gagagagggggaacaaaaaattgaaggaggaaaagagggagagaagttgaactttgaagtgtgtctcacaagactcattcattaaag ttacaacaagtgttacacatgcttctatttatagtctaggtaacttccttgagaagctagaacttaactacacacacctctctaataactaaga taacctccttgagaaatttccttgagaagcttccttaagaagattcctagagaagctaaagcttagttacacacacctctctaataactaagt tcacctccttgagatgagaagctagagccttagctacacacacccttiitaatagctaaactcactctattccaaaatacatgaaaatacaa aaaagttcctactacaaagattactcaaaatgtcctgaaatacaagactaaaactctatactactagaatggtcaaaatacaaggtccaaa agaaggaaaaacctattctaatatttacaaagagagtggacccaaccttagtccatgggctcagaaatctaccctgaggttcatgggaat cctagggtcttctttagtagctctagtccaattttcttggagtcttctatccaatatccttgggggtaggattgcatcatgtagtacaagagag gggaatatatatacagttgtaagttgtaactacctaatcaaacccaactgactcaccatacacagaaaaacaatgtacaaaggataatag aaaaactgaaactgagatatactcattacatagaagaattacatgatgaatctgaaaattttaattgggaaactgaggacaataacaagg ctttcagagttcattttgacaataggtaaattatggacttcaacttagacctcaagggtatgcttgggagtggggttttagaggaaaaggg gaaggagggaaattttttaattctagtaaatattctctattttgattaatttttaaaataaaacaaataaacttatagattagcattcacttaatgt tttttttacctgtactataactttccaaacaaatagtagaaaatgtttcaaatattccccagaactgtttcagtgaacaaagttcaagccagaa aaaaagcaagcagaggctaaagaagtatatcttattgtgaagagtaatctcaattggttaattatcgaattgtatcattttacaatagaaaat tagaagtgggttgattagtttatacgaacaattatttaaatagggttgatggtgtggttaattactgatcatatgttaagactatgagtcgatg accagcctcagtgcagtcattttaagttccattattttttaattgtgcttatgtttaactttgtccttcttttaaagggagatgtaaaatttgctgaa gttcttgaaaagatgggagctaaggttacatggtcagagaacagtgtcactgtttctggaccaccacgagatttttctggtcgaaaagtct tgcgaggcattgatgtcaatatgaacaagatgccagatgttgccatgacacttgctgttgttgcactatttgctaatggtoccactgctata agagatggtatggtttagctgtttgtttttgctcaagagcttgttttcacatatttgtggtcaagagcggtttagctgtttttttttttaaattgtgg ttaatgaaattattataattatactaatattgaaattggatcactaaccatgtgaaatgcttgaatttttagcttgaaaacttcttttgtggatgatt tttcttttatctatgtagtgtggggcatctatgttgttcctttaagctttgtgtcatagttgtacaacctggtctgtgggctggtccagttcttact catgactgtcttttgcagcaaactggttaaacttgggtgacctgttgacccacccagattggcctgttcttttttaaataaaactccaaaagg ctacttataagatttcaacatgatacttgaatgaccacccttactttaaaggtcattatgccatcagaccccttgattctctgttcagttatgttc ttattcttattattttttaatttatattattatccaacgatctgatctttgtacatgatgctggacaatcatcaaagctagtttggttacatcatataa aatactatttcaatgactgggccttattattttctggtttgggttatacaactgtcctttgatgtacttttgaatgcttcaatagtatttttcataatc atggaaggcactagagtgcagtgcatattgcacaaggttctttaatggcatcttgaatttgttagaacatggagttatgatatacaaccatt cctatgtcttcatctaatagctaaagcttttggcgtagttggttaacatggtattggaatcttattttaaaggtccatcttattcgcaagtacaa ggcaggtggacctgcgcattattcacgtgccaggctcaaagggattttgtatgagggggaatttttggaatataatatatagaatcattca tgtggttcacctatcatgtgtcaactcaagtttttgtcctagttgtattattgcagtgtctaaactaggcatgatcttctgtggaaggaaattta acctaaggaacttgaatgcttcttgttctgagatctttattttttttctccaatctttttaatacttgaaaggttttagttgtatctataaagggtgc agaattagggggtcagcttttctgttgtaagcgtgaattaagtgcattttatgttgttccctattttatacatttgaactatcaaccatatcattta gcaaacttctttgttgctcagattcccatttattcttgtttcctctattttttagtggcaagttggagagttaaagagactgagaggatgatagc aatctgcacagaactcagaaaggtcttgctaattcctttatggtttctatattactggactttttacatctcactgacctactactgtcttggtat ttcagctaggagcaacagttgaagaaggtcctgattactgtgtgattactccacctgagaaattgaatgtcacagctatagacacatatga tgaccacagaatggccatggcattctctcttgctgcttgtggggatgttccagtaaccatcaaggatcctggttgcaccaggaagacatt tcctgactactttgaagtccttgagaggttaacaaagcactaagcattttgtacattgagtagggaagagagagagatatatataaatact cacaaagcagtgagtatatggcttgcttttgtttctaaacattcctttataaggacttgagataatttgtattgtttaaaagagccattggttct gttgtatcaaagtaatttaattttcagtaccgacttggctctactcatatgtggtggtgtacattgcatctttgcatttgattccatatctattgg gatgggaccatacattttttgtttattatttaagtcaaacatatcagataatatgtggtgaccagaaaagtgtctagcaatcaaatgggtctgt gattgcatgtttgagttcaggacatttattaatgagtgacagaattttaaaaagctcgccaataggagttgccacatctgatcgagtcttctg taaacactaactgtaacttgagtttgataatcagattccccccgttggtaggtaatatgtaaatttcactatagattcttactgaggatgatgg tcttgacttcgaagtggtgagtgtaattctctaatctaaactttatatatatataaaaaaagaatgttaaaaacttgagtgacatacagcaaat agcaatgaaagcatgaccatggccttggggggccaaatggccatgtaccacttttccacctacttgagagccatggtcctgaatgaggt ccttttgtttcattttttttacaataaagaaagttcatattcttggcaatagcaaggcaaatcatttgtggaagtcacatgaaattcaccatagg cttcattgttcaaatcctttagtcactaaggcagggcctatgtaagaattttgactactcttgtaaatgctgtgcggtaaagactacgggaa aatataaattattgcatatctagaggtgaggttcatttctccgatccatttctccaagtaataaaaatatatataaattattaatatggtatgata tggttatttgtcctttaaatatgcgattataggttcaatctttggttaatctatcaaatgcatctcaatattttgagagaatagtttttagctcttga ctgagagatactttgagttaaaaaaatgtatttataaactattgtctattgaatttttattttttttgtaacaccacatgtgagtattttactaaatcc atgttacaatgtactgaatgttttacaatacagtctggtttgataataaaatatgcacaaagtccagcttatgtaactctttcaattcatggaaa atgatgatatgcgaattgaaagaaagaaaaccataatgtaagtgtattttttttttctttctcttctttaatattactcaatatcagattgcacatg ggaagggtactggctcatgtgggatattaatttttatcccttacctaaaaagagagaaagagaaaataactatttaaaaagagtaccacc accacctttttcgcttttaagttttgttctgttttcactactctttcatgcgttgtttgttggcttccgatagtgacgaatatgataatgattttacgt tgagaaaaaaaatgtgccatgtaaattccagagattgaaattttagcttcaaattaatatttattttattatcttttcaaattggttgcatgtgaa~ agaatttgaagttcttcaacaaggaaataaacacttcaatgctcaatccttagagtcagtcactagatcccaaaagaatgtgatgtttacac acattagtatatatatatatataaacacagcttatattatattaatgagtgatgcgcgaggacggtggtgacactacatggccaaaacaag aaatgtaatttaatttttttttctttaagtattactctatccttgaatattagtcttaaatcttcaaagaccttgcgaacgaagcaatcttgtcctga tcctgtgattgttctacactagtccttacgtgtacctaagcacatgatactttgctgccctaacataaattgtaccataaggattcttgggga gatgcttttgccttcattttcaagtttgtttacactttcaagtcgttttttcaatgcattctctttcctttctgggaccccttgtctttaacacgcgc gcacacaaaaactagtagacaataattagtactacttgggttccattaaattgtaactacatatacatgtgttttttttttcttggatcaactgc atatacatatgttttatgagtttcattgaatttatatttacacaaacagttattaaaacataatgtagagccttgtcattaacctgatgttaggatt ccgttcaaaagagagacgacaaggataatactaatactagtagattccacgcattcaaccctagttagtttagctatgacaaattaagcat ggtaagaaaaggggaggagaaagtaagaatgaacatataacaaattgtgattgaacttttccatgacgtaatgaaaacattaatttt aagataagcttcaactcctaagaagagatatgtcaaagaaacttaggattttttctctatttataacggtaaattactcatccttttaaatgatt aatttgcgttgttgaattcgttgtaaagggaaaatcaagaagtctcttcacgggaaagttatatcaaagtatcatatactagacttcatggct agcttttactttgattataagtaatgcatgcaattaatgggcaaataaattatttgaaaccaactaaagtacaaataattttcctccaaaacct ctcaagttcgcattgaaattaaataaaccaatgcatattaaggcgtaaatctaaaccatgtttgtttcatcttgtattgtatatcatagtattaat aaggtactttgaatttagttgttattgaccgttaaatttaggggtgagttgttttactatctcttactcaattgcttttattcaacgcaaattctagt aggattttcagcccaaattaaaagaagttttacggtttgattctctacaaacttgaattgagatttctaatttcagaaatcaataattgcggtct taattaactctataatcaaaccttttaacccaatctttttctcaattctctgaattaagacaatcaaaatttaaactcacacgaatctcacacgc cttcccacggtagagaaatatagggagtcccttaatagcaaaagcctcaaaattcagaaaatctcatccattgcatttgcacattcaacaa accacccattattatgttcccttaataaatctcacacttaaaaaccctcctcacccataattaacccaaaaggaagtttcctccacacaaaa aatatccttaaacaaagagcctctataaatctattttaaaaaaacccccaaatttaagga SEQ ID No. 32 with double mutation (SEQ ID No. 36) aaaagtctgaatgaagtgaagttgttgtgttagggggatgctgaatttgattttaatttaatttaaataaattacctgtgtaaaggattlttgta ccgccttttaatcacaaattgtcgtgtatcgaaagtttgttgaattttatagtaactatcttggaggttatacctagtaggatttctgattagtta accatgtaaatttttttaatgggtttgtgtttgttttaactgatgttgtttttgatatgtacgtggtaagtgtgatgagtttgtgcatatcttgatca aagactgaagtgaagttgttgtgtttggggggttgactcttttaggaagaggatttgagggaatttcgecaatgggggagcagaactcc gggacaccctgagaattttgagactccgggaattgaagttacaacaggtttgatatgagttagagtttgtataatagaatagtaattcttttt attttttatttttattgtttatttatccattattgctatttttgtaggtcctcttggtcaggggattgccaatgctgttggtttggcccttgcagagaa gcacttggctgcaagatacaacaagcctgacaatgagattgttgaccattacaegtaaaaataactaaatcatacacaacttgcaagact ttagttgttggtgttttgctaatggcgtttgttttatgcaggtatgctattctgggtgatggttgtcaaatggagggaattgcaaatgaagcat gctcacttgctggccactggggactggggaagctgatagcattttatgatgacaatcatatttctattgatggtaacacagagattgcgtt caccgagagtgttgatagtcgttttgagggacttgggtggcatgttatttgggtaaagaatggaaataatggctatgatgatattcgtgct gccattaaggaagcaaaagctgtcaaagacaaacccacattaatcaaggttagtttactaattgtggctgatatgcatagatttctggc ttgtagttaccataacaatcataatctgtcatgatttatagggattcttttaaactaaggttataaacatgatatgttactaaagactgcattgc attgtagtacctcatttgagaaactggaagttataggtgggaaatcaaaatagtaaattatgggtcagtttattaagtgtagctggtttgtctt ttgctaactctatcatttcacaggtcaeaacaaccattggttatggttctcctaacaaggctaactcctacagtgtgcatggaagtgcactg ggtgccaaagaagttgatgccaccaggcagaaccttggatggtcacatgagccattccacgtgcctgaggatgtcaaaaagtatggat gatgggtttagagatttcttttttcctgtgaeactgctgatgtttataatgatactgaataagaattgcttgtctgtecccaggcattggagtc gccacacccctgagggtgctgcacttgaagctgagtggaatgctaagtttgctgagtatgaaaagaaatacaaggaggaagctgcag aattgaaatctattatcaatggtgaattccctgctggttgggagaaagcacttccggtgagtaaattct~actcacaggtttttcttacatgt ttgtaacttttcaaggtttggattacatactatccaagttgatcatgatttcagtttgatttggtagtatggggcttcaaaaagttattccaaat attaaaacetggcttccaatttgatttcagacatacactecagagagcccagcggatgccaccagaaacctgtctcaaacaaaccttaat gcccttgcaaaggttcttcccggtctgcttggtggcagtgcagatcttgcttcttccaacatgaccttgctcaaaatgttcggggacttcca aaaggatactccagcagagcgtaatgttagattcggtgttagagaacacggaatgggagctatctgcaacggcattgctcttcacagec ctggactgattccatattgtgcaaccttetttgtattcactgactacatgagaggtgccataaggctttctgcgctgtctgaggctggggtta tttatgtcatgaeccatgattcaataggacttggagaagatgggccaacccaccagcctattgagcacctagcaagettccgggcaatg ccaaacattttgatgcttcgtcctgccgacggtaacsgaaacagccsgagcatacaaagtggccgtgctcaaeaggaaagagaccct ccattcttgccctatccaggcaaaaactgccccagcttcccggaactthcattgaaggagttgaaaagggtggttacaccatttcggga caactccactggcaacaagcctgatgtcattttgatcggaactggttcggaattggaaatcgctgccaaagctgctgatgacctaagga aggaagggaaggctgttagagttgtttcccttgtttcttggggaactttttgatgagcaatcagaagcatacgggagagtgttttccctg ctgctgtttcagccagagttagcattgaggcaggatcaacatttgggtgggagaaaattgttggagcaaagggaaaagcaataggcat tgatcgttttggagctagtgctccagctggaagaatatacaaagaatttggtatcactttggaagctgttgttgctgcagctaaagagctt atctagaacttttgatttttttttgccttctggttttggttgagagcattccatgtcatgaataagaaaaggttaaatatccttcgattgggaat ttgggattctaagtgaagaagcaacatagatcaaagaattttgtgaacttgtaataactatttgacaatttagttttgcactgccacatggtta aattcaatgtttgatcatatcaaccatagatgctagtttatactacttgtataatttgtttcacttgcagattcactcttagcatttgagtgtttgg atggccgtgttttgttcattaagaaatgttgacatggatagtttgttgcatggtaaattggtgattaatacctttttaagcttcttttggcaagtt gttaaaaagtgttttgttttaatctctagttaatctaaaaatgcctacttattttattttgactttcaaaacttgtctatatgccgagtataaaaaaa acttgtctatataagttccttatggaaaaaggacctacaaaataatttaaaaatgctgaatttgttaggaagtttgacaactttagacatWzaat aattgtttttttttcatatatataattgactttcaaaacttgtctatatattataaattcgttatggaaagggcgaccacacgtaaaacgtaacat gccaatctctccctagtgaactgttattctcattcagtttttgtaagttcaccttcaaattttcaattttttttttgacaaaaatatctttgatggaac acgttaggggtgtaaattcaccattcatcatttcattcattatacacaatagtctttcataatccaatgaaaacttgtttttgttgttatttttttctg aaaaatctttataaaataaataaaaacatttttttgttataaatttcagttgaaatacataaccattaattctacagagtgttaatgttgatgtaaa ataaaaaaatattggatatcaaacttaatgaacagaacaaaaattacaaaattgtacaatttaaatgataaaaaaccaaattcacaaaaata aaaattaaggacgaaatttgagaaatgataattaaaaacgattaaaaatataattaaactaaaatttattatgtaattctttaatatatatatata tatatatatatatatatatatatatatatatataataaaagttttacattataattttgaaatgaagtatttgataaacgaacaacccacccttggg gttggtgagagtgaaacggagaacagtgtctcecteacttggtcttctgagtcgagtcctattcatcaccaacccactcgtcaaaattgtt atttcagttcctagttgctacaacttccagctggtgaaaaatagtcaacagagactacaatattctaataaaatagaataacaaaatc aaaaatttctacaattatagaaaaagtttagttttgtagattgttaacataaagatttttcctattaactaattaatta~aaagtcatcttatatataa gttttaaagtaattatcttatatatgtacccaaaagttttaaagcaattattataaaaaagtaaaattttatcatatacaataatctataattacat attttattccacttttaccaataaatttcctcataaacacttataagaaaaaaagtaagtaaagaataaaataagcttttctataaactataaac ttttttaagaaatttgttcaaacatatttttatgacatgtcaatgcttgagagatataaggtgagttaaatcataaatgattaaagaaaaataaa agaagaaaaagataattaatttaattttttattaacattctaacaaattaacattatataaataaaaataatatttcaataattggatcaataatac tattgttcttaaacaccaaaccaaccttcctaaagtcctaatctaatccaaaagccatcattcattUccttggtaggtaaagttccaaaacct ttaccaaccttttcactcaattattttggtgtaagcaattcgacatgtgttaatgttagttggcaaccaaaaacccctttatgtgactcactcaa tccaacaacctctcacaccaccaacccccccataactcataaggccaaaaccatttctcacaaaacccttcattacacacattattatcatt atcacacacacaaaaaacctctcatttcaaagagagagagagatttcacagaccaaattgcagaggacgacaaagttcacaacttcaa ggaaaatcgaaatggcccaagtgagcagagtgcacaatcttgctcaaagcactcaaattttyggycattcttccaayyccaacaaacy caaatcggygaattcggtttcattgaggccacgcctttggggkscctcaaaatctcgcatcyygrtgmayaaaamtggaagcyttat gggaaattttaatgyggggaagggaaattccggcrtgtttaaggtttctgcatcsgtcgccgccgccgcagagaagccgtcaacgtcg ccggagatcgtgttggaacccatcaaagacttctcgggtaccatcacattgccagggtcyaagtctctgtccaatcgaattttgcttcttg ctgctctctctgaggtaaagtttatttatttatttatttctgtatccaaaaatgtaaattgttagtttgttaatttttgttagcagtgagagtcgaact acttggcttctttcttagtcatccaaccaaccttatatctccaaaatttatttattggttttttttggggttatgtggttaggaataggagtttgatg cgtggagtggattttgaatatttgattttttttttttttgtattattcagtgaaaatgaagcatcttgtcccatgaaagaaatggacacgaaatta agtggcgtatgatttagaatgatgatagaaatgtgtataggtggttttaatgtgtagcaataagcatattcaatatctggattgatttggacg tttctgtataaaggagtatgctagcaatgtgttaataatgtcttgttaaaagtatggatggctaaaataatcataaaaatcgagtgggagta gtatacatatctacaggaaatgtattaggtgaggcatttggcttctctattgcgagtaaggaacaagtaatctcagltaatgtgaaaatcaa tggttgatattccaatacattcatgatgtgttatttacgggaacgcaatattgactgttgattttatctgcagctgagattatatactatatcctt ccaaagaaatctttgactcttgattatccaagtatggttgtattaccaattttagctctagaagataatccctcccccaaaacacaaattaga tttttattcttatttagggaacaaetgttgtagacaacttgytgtayagygaggatattcattacatgcttggtgcattaaggacccttggact gcgtgtggaagaygacmaaacaaccaaacaagcaattgtkgaaggctgtgggggattgtttcccactaktaargaatctaaagatga aatcaatttattccttggaaatgctggtactgcratgcgtcctttgacagcagctgtrgttgctgcaggtggaaatgcaaggtctgttttttgt tttgtttgttcatcatgatctctgaattgttcctcgtataactaatcacatcagactatgtgttcttcctccatcctgttataatctaaaaatctcat ccagattagtcatccttctttaaatgaacctttaattatatctatgtatttatttaacatgtaaattagcttgtcaagtcaaagtctagcatataga tatactgattacactctgaggaatgcacctgagggtcttaatcatgatctatttcaaccttgccactttcttcttttattattagatcacctatcat gattactggtttgagtctctaaatagaccatcttgatgttcaaaatatttcagctacgtacttgatggrgtgccccgaatgagagagaggcc aattggggatttggttgctggtcttaagcaictyggtgcagatgttgattgctttcttggcacaaactgtccacctgttcgtgtaaatggga agggaggacttcctggcggaaaggtatggtttggatttccattagaataaggtggactaactttcctggagcaaaattctaatttataccct gtttccccctctttagaataagacactaagggtatgtttaggagttgggttttggcgagaaagggaagggagggcaattttttttctaataa cctctatttaaaaacaagatatttttcctccattccctttccctttaaaacctcagttccaaatataccgtacttgaattatattttggaaggtgta ttggttggagacctttccttttcagaggttatccctcacctttattatagcctttctactctcttaatgagttcattgtgcattgagtcattgaactt cctgtgaaaagaaattgtttacttttctttatttgttacctacatccttattcctgttttaaaaaatactaagttttcttttagttatgccttcccctcc ttattctctccaaagaaaatataatagcgaatgttggtttatccattgtgaatcttattatcctatttcacatgcaggtgaaactgtctggatca gttagcagtcaatacyractgctttgcttatggcagctcctttagctcttggygatgtggaaattgagattgttgataaactgatttctgttc catatgttgaaatgactctgaagttgatggagcgttttggagtttctgtggaacacagtggtaattgggatargttcttggtccatggaggt caaaagtacaagtaggtttctatgttttagcattacatcactttttagtatccaaaatgcaatgaaatcaaaactcatgttttctatcaggtctc ctggcaatgcttttgttgaaggtgatgcttcaagtgccagttayttmctagctggtgcagcarttactggtgggactatcactgttaatgg ctgtggcacaagcagtttacaggtattcatgcttgacactattttctattatcttttattttatggtctatactgtatcattcctaattcaaccccct tcttttctctttcccctcacttccaaaaaaatagagcttatcattgtattcttaatagctcttgtatgtcctttttcgtctcttgagcagattctacc tatttcattaacagtgataaagataaaaataaattgtcaagtaaagcaagttagcatgtcagataatgatgcttcaattgcaaaattggtgaa agcttgcacagtacattagctttggtgacaattgtgatgtagatagccataacctcccatgcaacttattatgttgtttgcttaaacttcttttg cacttaaacacggattagagagagtgaggatgaacaataataacagacacaaagcttagttttataccacccggcacccagtggtgaa gaccaagcagtatgagtgagatcaatggcagcatctgattgaagcttcttgtggtatttttggagatgaaatccgaggcgaattagggca tctggctcaacaatagccattggttcaaacttgcttttaataaaattgattacagaatcaaattcttgaggaagccttcaagaactacatcat gatgttccctgtgcaaaacaggttcaccgacaaaagagaacatctacaagttcctttacacatgccaaaaattcctcaactgaacaattg ccaagagtcatgttgcgaacttcaggttggagttgacgaaatttggtgcatgtatgattctggaaatgagcatgaagttttttcctaagctc ataaaagtgaatgcagccaagaaccctagataggattgaatcggagagaggcttgaagccaagataacagcaactgatcttgctgttc ccatgctgcgtaggactcattgattctaccaagatcacaatcttctgtggtgagaaaatgagggtgaattgtcaaccaataaagaaaatg gtgaaggctgagtcttgatgataggcttgatttgcttgcgctgaagaagaacgttattgttgtagagtttctcagtgattgtatgagagtaa gttacaggtgcgattggagatgacggacttgtggtgggaggagggtaagtgttaagtggtggaatgcgtatcagaggtggttgccca gccaaagaagctggttgcggtggaggaggtggtggtgcagtggaagccatgggttttgatgcttttgagagaaaacatacgaaactg aactgtaaacttttgtattattgattagctgatttggtagtacaagagaggaatatatatacagttttaatgtaactacctaaccaaacatgag gaactctccatacacagaaagacgtatacaaaggataacagacaaacagaaacttagatatactcatacagagaagaattacaggatg aatctgagaattttaattgggaaactgaggaaaatagcaagggtttcagaattcattttgacgataggcaaatcatggacttaacttagac ctcaagggtacgcttgggagtgggggtttttagagggaaaagggaaggagggcaaacttttaattcctaataaatattctcttttttgatttt ctatagtatgtataactattcaaataaatagtagaaaatgtttcaaatattccccagaactgtttcagtgaacaaagttcaagccagaaaaa agaagtatatcttcttgtgaagagtagctcaagtggttaattgtcaaatttgtatcattttagaatacaaaattagaagtggtttgattagtttat acgaacgattatttaaatagggttgatgatgtggttaattactgatcatatgtgaagactgtgagtcgatgaccagcccagtgcagtcattt taaattccattattttaatttgtgcttatgttaaactttgtccttctttcaaagggagatgtaaaatttgctgaagttcttgaaaagatgggagc taaggttacatggtcagagaacagtgtcacygttwctggaccrccacragattyttctggtcraaaagtcttgcraggcattgatgtcaat atgaacaagatgccagatgttgccatgacwcttgcygttgtygcactatttgctaatggtcmmactrcyatmagagatggtatggttt agctgtttgtttgtgttcaagagcttgttttaacaaattgttttttttaattatggttaatgaaattattataattacactaatattgaaattggatca ctaaccatgtgaaatgcttgaatttttagcttgaaaacttcttttgtggacaatttttcttttatctatggattgtggggcatctatgttgttccttt aagcttcgtacaacctggtctgtgggctggtccagtccttcttactcatgacagtcttttgcagtaaactggttaaacttgggtgacctgttg acccacccagattggcctgttctttttaaataaaacttggctacttataagatttcaacatgatacttgaatgatcacccttactctaaaggcc gtcgtttttttcctggcttgaatgctatttcaatgactgggccttattattttctggtttaggttatacaactgtcctccaattgacttttgaatg cttcaatagttttcttcttaatcatggaaggcactagagtgcatattgaatatgttagaacatggaaggcttaaatatcttutagtctttgcaat ttaacgtttttttgcttttagtccttgcaaaattataatttttttttagtcctgactaattatgtttgttttgtttttgagggcgagccctggtgcagc ggtaaagttgtgccttggtgacttgttggtcatgggttcgaatccggaaacagcctctttgcatatgcaagggtaaggctgcgtacaatat ccctcccccataccttcgcatagcgaagagcctctgggcaatggggtagaaaaagaagaatgctttagataacactttttttgttactgtt caaagcactatctaaagtgctttgaggactaaacacaaaacaaacataatttgcaaggactgaaaaacaaaaaaataattttgc~gga caaaaaaacaaaaaaaaaaaacaaaattgcaaggaccaaaaatatatttaaaccaacatgaaattatggtataaaaccattcatatgtctt catctaatagcttaagcttttgggatagttggttaacaatatggtattagagtcttatgatttttaggtggtctttgagttcaatccttgctgctc ccagttctagttaatttctttttggtccacttcaaataaaaagttgaatttaagggtaaggcagctggacctgcgcattaatcatgtgtcagg ctcaaagggcttttgtatggggggcatgtttggaatataatatagaatcattcatgtggtttcacctatcaaggacaactctagtttttgtcat acttgtattattacagtgtctaaactagacatgatctttttccggaaggaaatttaacttaaaaggaacttagatgcttcttgttctgtgatcttt tttgctgctcagattctcctttggactatctaccatatcatttagcaaacctgttcactgctcagattctcatttattctttgtucctctatwj~ca gtggcaagttggagagttaaagagactgagaggatgatagcaatctgcacagaactcagaaaggtgagtgtcttgctaattcctttatg gtttcgatattactggactttttacatctcactgacctactctgtcttggtatttcagctaggagcaacagttgaagaaggtcctgattactgt gtgattactccacctgagaaattgaatgtcacagctatagacacatatgatgaccacagaatggccatggcattctctcttgctgcttgtg gggatgttccagtaaccatcaaggatcctggttgcaccaggaagacatttccygactactttgaagtccttgagaggttmacaaagca ctaagcattttgtacattgagtaggaagagagagagagataaatactcacaaaacagtgagtatatgcatggcttgcttttgtt-tcttaaca tcccttgtaagaacttgagataatttgtattgttggaaagagctattgauctgttgtatcaaagtaatttaatttccagtacagacuggctct attcctcatatgtggtggtgtacattgcatctttgcatttgatcccatttctattgggataggaccatacctttttttgtttattattcaagtcaaac ttagcagataatatgtggtgaccagaaaatagtctagctagcaaatagacctgtgattgcatgtttgaattcaggacttcaggacatttaat taatgagtgacaatgttaaaaagctcgccaacaggagttgacacatctgattgagtcttctattaacactaactgtaacttgagtttgattat cagattcctcctgttggtaggtaatatgtaaatttcactatatatttaccgaggttggtggtcttacttgactttgaagaggtgagtgtaattta aacttttatatcaaaaaaagattgctaaaagcttgagtggcatgcaacaaatagcaatgaaagaatgactatggccttgggaaccaaatg gccacgtaccacttttccaccaacttgagagccctggtcctggatgatgcccctttttttttttcatttctttgacaataaagaaagttcttattc ttggcaattgcaagtcgtttgtggaagtcacatgaaattcaccataggcttcattgttcaaatcctttagtcactaactaaaggctggaccta tgcaagaattttggctactcttataaatgctgtgcggcaaagactacggaaaaatataaattattgcatatctagaggtgaggttcattgct cccatccatttttccaagaactaaaatatatataaattattaatatgatattacattgaaaaataatatttt-tcttttaaatatgtgatcataagttta attttaagtctattcatacgaaaaaaatatttattagaaaagattaatttattaaatggatctcaatattttaagaaattaacttttagctctcaac caacagatgatttgagttaaaaaaatgtatatataaactattgcatatctgctgatttttgtttgtaacaccaataagtgggcattttactaaat ccatgtgacaatgtactgaatgttttagaatacagtctggtttgataataaaacgtgcataaagtccagcttatgttaactcttaattcatgga aaatgatgatatgcgaattgaaagaaagaaaaccataatgtaagtgcagttttctctctcttttttaatattattcaatatcagattgcacatg ggaaggggtattggctcatgtgggatattagtttttgtcccttacctaaaaagagagaaagagaaaaataacaatttaaaaagagtacca ccgctaccacctttttcgcttttaaatttttgttctgttttcactactctttcatgcgttgtttgttggcttctgatagtgacgaatatgatataatga ttttatgttgggaaaaaagtgccatgtaaattctagagattgaaattttagcatcaaattatttattttatcaccttttaaaatttgttgcatgtga aagaatttgaagctctccaacaaggaaataacacttcaatccttagagtcatcctctagatcccaaaagaatgtgatgtttatacacattag tatatatatatatatatatatatatatatatatatatatatatatatatatatatatatatatagggtttatattatattaatgagtgatgtacgaggac ggtggtgacactatatggccaaaacaagtgtaatataattatttttttttctcaagtattactctatccttgaatattattagtcttaaatcttcaa gcaccttgtgaacgaagcaatcttgtcc FMVS35S90 enhancer (SEQ ID No.37) aagcttcccgggccggccgcagctggcttgtggggaccagacaaaaaaggaatggtgcagaattgttaggcgcacctaccaaaagc atctttgcctttattgcaaagataaagcagattcctctagtacaagtggggaacaaaataacgtggaaaagagctgtcctgacagcccac tcactaatgcgtatgacgaacgcagtgacgaccacaaaactcgagacttttcaacaaagggtaatatccggaaacctcctcggattcca ttgcccagctatctgtcactttattgtgaagatagtggaaaaggaaggtggctcctacaaatgccatcattgcgataaaggaaaggccat cgttgaagatgcctctgccgacagtggtcccaaagatggacccccacccacgaggagcatcgtggaaaaagaagacgttccaacca cgtcttcaaagcaagtggattgatgtgatatctccactgacgtaagggatgacgcacaatcccactatccttcttaattaa FMV35S46 enhancer (SEQ ID No.38) aagcttcccgggccggccgcagctggcttgtggggaccagacaaaaaaggaatggtgcagaattgttaggcgcacctaccaaaagc atctttgcctttattgcaaagataaageagattcctctagtacaagtggggaacaaaataacgtggaaaagagctgtcctgacagcccac tcactaatgcgtatgacgaacgcagtgacgaccacanaactcgagaacatggtggagcacgacacacttgtctactccaagaatatca aagatacagtctcagaagaccagagggctattgagacttttcaacaaagggtaatatcgggaaacctcctcggattccattgcccagct atctgtcacttcatcgaaaggacagtagaaaaggaagatggcttctacaaatgccatcattgcgataaaggaaaggctatcgttcaaga tgcctctaccgacagtggtcccaaagatggacccccacccacgaggaacatcgtggaaaaagaagacgttccaaccacgtcttcaaa gcaagtggattgatgttaattaa GmTerm Barn (SEQ ID No.39) ctgcagggatcctggttgcaccaggaag GmTermEco (SEQ ID No.40) gaattcccgggtatggtgaatttcatgtg BnMUT2PST (SEQ ID No.41) gacttctcgggtaccatcacattgc BnMUTkpn (SEQ ID No.42) cacctgcagcaaccacagctgctgtcaaagaacgcattgcaataccagcatttcc GmRubPac (SEQ ID No.43) aatttaattaattcataaatatgttac GmRubbot (SEQ ID No.44) ggtcttctccttcttagttctcaaetacttgttettctgctgccagatttcaattttccttaaagttgtgaac GmRubtop (SEQ ID No.45) atctggcagcagaagaacaagtagttgagaactaagaaggagaagaecatggcccaagtgagcagagtgeac GmRubKpn (SEQ ID No.46) ggcaatgtgatggatcccgagaag ZPPDK1 (SEQ ID No. 47) gcgccatggcggcatcggtttccaggg ZMIPPDK2 (SEQ ID No. 48) gcgggtacctcagacaagcacctgagctgcagc EcPPS1 (SEQ ID No. 49) gcggcatgcccaacaatggctcgtc EcPS2 (SEQ ID No. 50) gcggatccttatttcttcagttcagcca EPSPS motit (SEQ ID No. 51) ALLMZAIPLA, wherein Z is not S or T EPSPS motit (SEQ ID N6. 52) EIEIZDKL, wherein Z is not V EPSPS motit (SEQ ID No. 53) FG(V/I)(K/S)ZEH, wherein Z is not V EPSPS motit (SEQ ID No. 54) AL(K/R)ZLGL, wherein Z is not R EPSPS motit (SEQ ID No. 55) GLXVEZ₁DXZ₂XXXA(I/V)V, wherein Z₁ is not T and/or Z₂ is not E EPSPS motit (SEQ ID No. 56) ITPPZ₁K(L/V)(K/N)Z₂, wherein Z₁ is not K and/or Z₂ is not T EPSPS motit (SEQ ID No. 57) TIZ(D/N)PGCT, wherein Z is not N or L EPSPS motit (SEQ ID No. 58) (D/N)YFXVLXZXX(K/R)H, wherein Z is not K EPSPS motit (SEQ ID No. 59) (I/V)VEGCGG(I/L/Q)FP(V/A/T)(S/G) EPSPS motit (SEQ ID No. 60) (I/V)VVGCGG(J/L/Q)FP(V/A/T)E EPSPS motit (SEQ ID No. 61) (I/V)VVGCGG(I/L/Q)FP(V/A/T)(S/G) EPSPS motit (SEQ ID No. 62) (I/V)VVGCGGKFP(V/A/T)(S/G) EPSPS motit (SEQ ID No. 63) (I/V)VEGCGGKFP(V/A/T)E EPSPS motit (SEQ ID No. 64) (I/V)VEGCGG(I/L/Q)FPV/A/T)E; EPSPS motit (SEQ ID No. 65) (I/V)VEGCGGKFP(V/A/TXS/G).

[0157]

1 70 1 3836 DNA Brassica napus 1 gcatgcagat cttaaaggct cttttccagt ctcacctacc aaaactataa gaaaatccac 60 ttgctgtctg aaatagccga cgtggataaa gtacttaaga cgtggcacat tattattgac 120 tactagaaaa aaaactcata caccatcgta ggagttgggg ttggtgaaga atttgatggg 180 tgcctctccc ccccccactc accaaactca tgttctttgt aaagccgtca ctacaacaac 240 aaaggagacg acagttctat agaaaagctt tcaaattcaa tcaatggcgc aatctagcag 300 aatctgccat ggcgtgcaga acccatgtgt tatcatctcc aatctctcca aatccaacca 360 aaacaaatca cctttctccg tctccttgaa gacgcatcag cctcgagctt cttcgtgggg 420 attgaagaag agtggaacga tgctaaacgg ttctgtaatt cgcccggtta aggtaacagc 480 ttctgtttcc acgtccgaga aagcttcaga gattgtgctt caaccaatca gagaaatctc 540 gggtctcatt aagctacccg gatccaaatc tctctccaat cggatcctcc ttcttgccgc 600 tctatctgag gtacatatac ttgcttagtg ttaggccttt gctgtgagat tttgggaact 660 atagacaatt tagtaagaat ttatatataa tttttttaaa aaaaatcaga agcctatata 720 tatttaaatt tttccaaaat ttttggaggt tataggctta tgttacacca ttctagtctg 780 catctttcgg tttgagactg aagaatttta ttttttaaaa aattattata gggaactact 840 gtagtggaca acttgttgaa cagtgatgac atcaactaca tgcttgatgc gttgaagaag 900 ctggggctta acgtggaacg tgacagtgta aacaaccgtg cggttgttga aggatgcggt 960 ggaatattcc cagcttcctt agattccaag agtgatattg agttgtacct tgggaatgca 1020 ggaacagcca tgcgtccact caccgctgca gttacagctg caggtggcaa cgcgaggtaa 1080 ggttaacgag ttttttgtta ttgtcaagaa attgatcttg tgtttgatgc ttttagtttg 1140 gtttgttttc tagttatgta cttgatgggg tgcctagaat gagggaaaga cctataggag 1200 atttggttgt tggtcttaag cagcttggtg ctgatgttga gtgtactctt ggcactaact 1260 gtcctcctgt tcgtgtcaat gctaatggtg gccttcccgg tggaaaggtg atcttcacat 1320 ttactctatg aattgtttgc agcagtcttt gttcatcaca gcctttgctt cacattattt 1380 catcttttag tttgttgtta tattacttga tggatcttta aaaaggaatt gggtctggtg 1440 tgaaagtgat tagcaatctt tctcgattcc ttgcagggcc gtgggcatta ctaagtgaaa 1500 cattagccta ttaaccccca aaatttttga aaaaaattta gtatatggcc ccaaaatagt 1560 ttttaaaaaa ttagaaaaac ttttaataaa tcgtctacag tcccaaaaat cttagagccg 1620 gccctgcttg tatggtttct cgattgatat attagactat gttttgaatt ttcaggtgaa 1680 gctttctgga tcgatcagta gtcagtactt gactgccctc ctcatggcag ctcctttagc 1740 tcttggagac gtggagattg agatcattga taaactgata tctgttccat atgttgaaat 1800 gacattgaag ttgatggagc gttttggtgt tagtgccgag catagtgata gctgggatcg 1860 tttctttgtc aagggcggtc agaaatacaa gtaatgagtt cttttaagtt gagagttaga 1920 ttgaagaatg aatgactgat taaccaaatg gcaaaactga ttcaggtcgc ctggtaatgc 1980 ttatgtagaa ggtgatgctt ctagtgctag ctacttcttg gctggtgctg ccattactgg 2040 tgaaactgtt actgtcgaag gttgtggaac aactagcctc caggtagttt atccactctg 2100 aatcatcaaa tattatactc cctccgtttt atgttaagtg tcattagctt ttaaattttg 2160 tttcattaaa agtgtcattt tacattttca atgcatatat taaataaatt ttccagtttt 2220 tactaattca ttaattagca aaatcaaaca aaaattatat taaataatgt aaaattcgta 2280 atttgtgtgc aaatacctta aaccttatga aacggaaacc ttatgaaaca gagggagtac 2340 taattttata ataaaatttg attagttcaa agttgtgtat aacatgtttt gtaagaatct 2400 aagctcattc tctttttatt ttttgtgatg aatcccaaag ggagatgtga aattcgcaga 2460 ggttcttgag aaaatgggat gtaaagtgtc atggacagag aacagtgtga ctgtgactgg 2520 accatcaaga gatgcttttg gaatgaggca cttgcgtgct gttgatgtca acatgaacaa 2580 aatgcctgat gtagccatga ctctagccgt tgttgctctc tttgccgatg gtccaaccac 2640 catcagagat ggtaaagcaa aaccctctct ttgaatcagc gtgttttaaa agattcatgg 2700 ttgcttaaac tctatttggt caatgtagtg gctagctgga gagttaagga gacagagagg 2760 atgattgcca tttgcacaga gcttagaaag gtaagtttcc ttttctctca tgctctctca 2820 ttcgaagtta atcgttgcat aactttttgc ggtttttttt tttgcgttca gcttggagct 2880 acagtggaag aaggttcaga ttattgtgtg ataactccac cagcaaaggt gaaaccggcg 2940 gagattgata cgtatgatga tcatagaatg gcgatggcgt tctcgcttgc agcttgtgct 3000 gatgttccag tcaccatcaa ggatcctggc tgcaccagga agactttccc tgactacttc 3060 caagtccttg aaagtatcac aaagcattaa aagacccttt cctctgatcc aaatgtgaga 3120 atctgttgct ttctctttgt tgccactgta acatttatta gaagaacaaa gtgtgtgtgt 3180 taagagtgtg tttgcttgta atgaactgag tgagatgcaa tcgttgaatc agttttgggc 3240 cttaataaag ggtttaggaa gctgcagcga gatgattgtt tttggtcgat catctttgaa 3300 aatgtgtttg tttgagtaat ttttctaggg ttgagttgat tacactaaga aacacttttt 3360 gattttctat tacacctata gacacttctt acatgtgaca cactttgttg ttggcaagca 3420 acagattgtg gacaattttg cctttaatgg aaaggacaca gttgtggatg ggtgatttgt 3480 ggacgattca tgtgtggtta ggtgatttgt ggacggatga tgtgtagatg agtgatgagt 3540 aatgtgtgaa tatgtgatgt taatgtgttt atagtagata agtggacaaa ctctctgttt 3600 tgattccata aaactataca acaatacgtg gacatggact catgttacta aaattatacc 3660 gtaaaacgtg gacacggact ctgtatctcc aatacaaaca cttggcttct tcagctcaat 3720 tgataaatta tctgcagtta aacttcaatc aagatgagaa agagatgata ttgtgaatat 3780 garscggaga gagaaatcga agaagcgttt accttttgtc ggagagtaat gaattc 3836 2 31 DNA Artificial Sequence Primer 2 gcatgcagat cttaaaggct cttttccagt c 31 3 32 DNA Artificial Sequence Primer 3 gaattcatta ctctccgaca aaaggtaaac gc 32 4 20 DNA Artificial Sequence Primer 4 gcgcaatcta gcagaatctg 20 5 20 DNA Artificial Sequence Primer 5 tccttcttgc cgctctatct 20 6 20 DNA Artificial Sequence Primer 6 gcgttgaaga agctggggct 20 7 20 DNA Artificial Sequence Primer 7 acctatagga gatttggttg 20 8 20 DNA Artificial Sequence Primer 8 actaagtgaa acattagcct 20 9 20 DNA Artificial Sequence Primer 9 gttccatatg ttgaaatgac 20 10 20 DNA Artificial Sequence Primer 10 tccactctga atcatcaaat 20 11 20 DNA Artificial Sequence Primer 11 gtaagaatct aagctcattc 20 12 20 DNA Artificial Sequence Primer 12 tcatggttgc ttaaactcta 20 13 20 DNA Artificial Sequence Primer 13 cagcttgtgc tgatgttcca 20 14 20 DNA Artificial Sequence Primer 14 cgatcatctt tgaaaatgtg 20 15 20 DNA Artificial Sequence Primer 15 ctctctgttt tgattccata 20 16 25 DNA Artificial Sequence Primer 16 cgcatcagcc tcgagcttct tcgtg 25 17 29 DNA Artificial Sequence Primer 17 ggtgagtgaa cgcatggcta ttcctgcat 29 18 29 DNA Artificial Sequence Primer 18 atgcaggaat agccatgcgt tcactcacc 29 19 25 DNA Artificial Sequence Primer 19 catttcaaca tatggaacag atatc 25 20 90 DNA Artificial Sequence Primer 20 cccgggatat tggaagttaa aggaaaagag agaaagagaa atctttctgt ctaagtgtaa 60 ttaaccatgg cgcaatctag cagaatctgc 90 21 20 DNA Artificial Sequence Primer 21 ggacgtggaa acagaagctg 20 22 20 DNA Artificial Sequence Primer 22 tctcaaaccg aaagatgcag 20 23 31 DNA Artificial Sequence Primer 23 ggttgaagca caatctctga agcttccatg g 31 24 31 DNA Artificial Sequence Primer 24 gatcttgggt cattttaatg ggccttctaa c 31 25 34 DNA Artificial Sequence Primer 25 aaataaaccc attaaccact aatgaaaaag ggat 34 26 28 DNA Artificial Sequence Primer 26 gcggagctcg agacttttca acaaaggg 28 27 35 DNA Artificial Sequence Primer 27 atcccgggaa gcatgcgaag gatagtggga ttgtg 35 28 23 DNA Artificial Sequence Primer 28 cgcccgggat tgaatttbaa agc 23 29 209 DNA Figwort Mosaic Virus Enhancer 29 tctagagcag ctggcttgtg gggaccagac aaaaaaggaa tggtgcagaa ttgttaggcg 60 cacctaccaa aagcatcttt gcctttattg caaagataaa gcagattcct ctagtacaag 120 tggggaacaa aataacgtgg aaaagagctg tcctgacagc ccactcacta atgcgtatga 180 cgaacgcagt gacgaccaca aaagagctc 209 30 309 DNA Cauliflower Mosaic Virus Enhancer 30 tgagactttt caacaaaggg taatatccgg aaacctcctc ggattccatt gcccagctat 60 ctgtcacttt attgtgaaga tagtggaaaa ggaaggtggc tcctacaaat gccatcattg 120 cgataaagga aaggccatcg ttgaagatgc ctctgccgac agtggtccca aagatggacc 180 cccacccacg aggagcatcg tggaaaaaga agacgttcca accacgtctt caaagcaagt 240 ggattgatgt gatatctcca ctgacgtaag ggatgacgca caatcccact atccttcgca 300 agacccttc 309 31 15941 DNA Glycine max 31 aaaaaatacc ttttagtaaa ataagagcgt ragatcaatc agacgttttc tctttgggac 60 ttctcattct taattgaatt gacaataact aaagtgaaac taaggctaaa atcaactcgc 120 ctagtcaagc tcgtccacaa aaataggttt ttgaaagttt accatgtcag tttcttacta 180 agtaaaaaag gatcatttgt aaggtccaac gccttaaaat gatcaccctt caaagtaaaa 240 gaatcacttg tttcacgcat aagtaagaac tacgtaggtc tgatttcctc tccaaaggag 300 ggtacgtagg agcaaaagcc ccgcttttgt cgaccttaaa aaataaaaag aaacaaaagt 360 taaggtaaca caatttccac aattctagaa ataaggttgt tgtctttcga gacaaacgta 420 agaggtgcta ataccttcct caaacgtaaa tacaactccc gaacttagaa ttttcatttt 480 gaccggtttc cttcggtttt cccgacgttt tccacaaata aacgttggtg gcgactccgc 540 gcatctttcc tcctttggaa agcgcaccca tgagcctcgc cctcgctcgc ccgcgaaggg 600 cacgttgcga cactaggtta ataagaagtt tagtccacat atctatggac ctcttaaggt 660 gattatcaaa gtggaagtgg tgacctacat gttggcccta ccagcttatt cgtatattta 720 cccccatcaa ccatgtatct cagctgaaac atgctatcaa tccaaatgtt atcagaggaa 780 catgagctgc atgttcaacc agaagtagtt ctagtcttaa tacaaatgtc aaatggcaca 840 agtgagattt tgaatttctg atgttgtaaa aatctcagga catgaatact attgggaagc 900 aattattcat acttcaccaa tccaaactga cccaaaattc tcaaatcaca tgaaagcaaa 960 aatgcatata acacgaagaa taagaagaag aggaactaac ctggggtttc gatgattaaa 1020 gcgttgttgt tgatgatgaa aacgatgatt atggagagaa attgttgttg aatggtgaaa 1080 ttgttataga aagagaacga agatagagaa aaagatatat agatttttca aggctcaaac 1140 cctaaaatca ccatgagaga gaacaaagat tgagaaacct acaaccacta tgagagagaa 1200 tgagcagaac agaagcgtga gatagagaac gagagttaag gtgcgagagg acacgaagaa 1260 caaaaggtgt gagagaaaga acaaaggagc ctacggtgtg agatgagaga atttgaaatt 1320 cttaccattt aggtggaatt tcaattctac aattttattc tattaaaatt attttaaaaa 1380 atgatgtcat tttaaattct ttaaaatctc atatccaaca actgaattat gatagaggta 1440 tttcaaattc acttaaaaaa attatcttat ttaaataccc catccaaaca tagcgaaatg 1500 ttcatgagaa ggatcaagtg gtttggaaac atagtactaa tggtgtttat acagttcatg 1560 gaatccttga tagataattt aaaggttgct ggaaattgga tgaaggtgtg gagattaaat 1620 attcttccaa aaataaagcg ttttatttgg agagtgttgt gtggttgtct cccctgtagg 1680 caaaagcttc gatgtaaagg agttcaatgt ccaataacct atgctttcta tccctcgatt 1740 attgaaaatg aatgacacat tttatttggt tgaaatcaag aaataagcat gtggcaagca 1800 acgggtattt gacaattcat agaacaaaag gtgaatgcag caaaagaatt aatgaactcc 1860 ttttcgatct acttggatca ctacatggag atattatcaa caaatttgat gttactttat 1920 ggagcagttg gaattcttgg aatgacaaga tatgaaatga acataccaac cctcctcttg 1980 tttctgtttc ggtttctatg cagtattttg ttgaatggca aagtgcaagg taatatgctc 2040 ctcaacatca attaacaaat gttcatgaca tctcttacca gctccaactt ggggacgttt 2100 gacaaacacc accgtcaagt ttccttaaat gcaacattaa tgttgctcat ttcaaggagg 2160 agaatagttt tggtgtcggc atgatactcc atcaaggaag attcgtcaaa gctcactcac 2220 gttttcgaca tgggtcgaca tgggttacct gacccaaagg ctgaggctta ggcttgggtt 2280 tgcttcaagt attgatctgg gcccagacta ttggtttaca taatatcatt tttgaaaacc 2340 taacatctaa aactcaaggt tgtttagagg tgcgccattc caaaataaga ttatcctatt 2400 tgtgcatgaa tgcgaccaac tatctcctgt ttcagcatta taaagtataa acaacaaact 2460 tctttaatca agggactaaa agatattgga catacaagct aaaagtgata gaatttgaga 2520 aaacaaatat tgacaacaat attcaagagg acactaaaac ataattctca aatttttttt 2580 gtttatttaa aataaagtgg ttcattaggt agctcttgaa aaaaaaaagt gattaacatg 2640 ctagtacatg ttaaaaaaag tgaataatat tctattataa gtaaagagga ataatttatc 2700 gatgtctcat ttttgagata gttcaccgaa gccaattttt ttactttttt ctcttcaatc 2760 aattttattt tgttaatagt tgtcattgtg gatggattat aataattttg aaatgattta 2820 aaatgagata tatattaata aatttaatta attcataaat atgttactaa atataaattt 2880 catggtatac tcaggacggt tataacggaa atcaaataaa taataaaata gaataatatt 2940 aatttgcagt aaaaagaata atattaattt attctgttta cactatgtat aacgaaatta 3000 aatatattca tttaatatga ttttattttt ctttaattta aaaacatgaa ttatttgttt 3060 cttattttat taccattttg ttcacttctc aattaataaa ataaaaatat attctacaat 3120 tatagtaaaa aggtttaatt ttatataatg ttagcataca gatttttctc tattaactaa 3180 ttaattaaaa attatcctta ttttaaggaa attaaaaatt atcatatata tataagtttt 3240 aaattaatta tcttatatat gtaccaaaaa gttttaaagc aattattata aaaattaata 3300 aatttatcat ataaaataat ttataattaa attttaaatt atcaattcat taaattaaat 3360 tatttaaaat ttttgaatga taatataata attttatcct ctactaagtc ccaacgtttc 3420 ctattttatt ccacttttag caataaattt tgtcataaac acttataaca aaaaaagtaa 3480 gtaaaaaata aaaaaaagtt tttcaataaa gtataaacta atttgtataa acttttagaa 3540 aaaataaagt tatacattga taatataaat tttttacata attatccgat caactcatta 3600 tatatgataa atttattgat tttttaaaat aattatctta aaataattta aacaatgatt 3660 tgcaattaga tgataatata aaattatttt acacactaca tgtattaaac tcaaactttt 3720 atatattagt ttttctaaaa actaattttt aactcaaaaa aaatgttact tataattttc 3780 ttatcttctt tttttataag tattttttaa gaaatttatt gaaacatgac catgcttggg 3840 tcaataatac tactctctta gacaccaaac aacccttccc aaactataat ctaatccaaa 3900 agccatcatt cattttcctt ggtaggtaaa gttccaagac cttcaccaac tttttcactc 3960 aattgttttg gtgtaagcaa ttcgacatgt gttagtgtta gttggcaacc aaaaatccct 4020 ttatgtgact caatccaaca accactcaca ccaccaaccc ccataaccat ttctcacaat 4080 acccttcatt tacacattat catcaccaaa aataaataaa aaaaacctct catttcagag 4140 agagagagag agacttcaca gaccaaagtg cagagaacaa caaagttcac aactttaagg 4200 aaaattgaaa tggcccaagt gagcagagtg cacaatcttg ctcaaagcac tcaaattttt 4260 ggccattctt ccaactccaa caaactcaaa tcggtgaatt cggtttcatt gaggccacgc 4320 ctttgggggg cctcaaaatc tcgcatcccg atgcataaaa atggaagctt tatgggaaat 4380 tttaatgtgg ggaagggaaa ttccggcgtg tttaaggttt ctgcatcggt cgccgccgca 4440 gagaagccgt caacgtcgcc ggagatcgtg ttggaaccca tcaaagactt ctcgggtacc 4500 atcacattgc cagggtccaa gtctctgtcc aatcgaattt tgcttcttgc tgctctctct 4560 gaggtgaagt ttatttattt atttatttgt ttgtttgttg ttgggtgtgg gaataggagt 4620 ttgatgtgta gagtggattt tgaatatttg attttttttt gtattattct gtgaaaatga 4680 agcatcatgt cccatgaaag aaatggacac gaaattaagt ggcttatgat gtgaaatgag 4740 gatagaaatg tgtgtagggt tttttaatgg gtagcaataa gcatattcaa tatctggatt 4800 gatttggacg tttctgtata aaggagtatg ctagcaatgt gttaatgtat ggcttgctaa 4860 aatactccta aaaatcaagt gggagtagta tacatatcta cagcaaatgt attaggtgag 4920 gcatttggct tctctattgt aaggaacaaa taatatcagt taatgtgaaa atcaatggtt 4980 gatattccaa tacattcatg atgtgttatt tatatgtacc taatattgac tgttgttttt 5040 ctccgcaatg accaagatta tttattttat cctctaaagt gactaattga gttgcttact 5100 ttagagaagt tggacccatt aggtgagagc gtggggggaa ctaatcttga atatacaatc 5160 tgagtcttga ttatccaagt atggttgtat gaacaatgtt agctctagaa gataaaccct 5220 cccccaaaac acaaattaga atgacatttc aagttccatg tatgtcactt tcattctatt 5280 atttttacaa cttttagtta cttaacagat gtcttgttca gcataaatta taatttattc 5340 tgtttttttt tagggaacaa ctgttgtaga caacttgttg tatagtgagg atattcatta 5400 catgcttggt gcattaagga cccttggact gcgtgtggaa gatgacaaaa caaccaaaca 5460 agcaattgtt gaaggctgtg ggggattgtt tcccactagt aaggaatcta aagatgaaat 5520 caatttattc cttggaaatg ctggtactgc aatgcgtcct ttgacagcag ctgtggttgc 5580 tgcaggtgga aatgcaaggt ctgttttttt ttttttgttc agcataatct ttgaattgtt 5640 cctcgtataa ctaatcacaa cagagtacgt gttcttcttc ctgttataat ctaaaaatct 5700 catccagatt agtcatcctt tcttcttaaa aggaaccttt aattatcaat gtatttattt 5760 aatatttaaa ttagcttgtc aaagtctagc atatacatat tttgattata ttctgagaaa 5820 tgcacctgag ggtgttcctc atgatctact tcaacctctg ttattattag attttctatc 5880 atgattactg gtttgagtct ctaagtagac catcttgatg ttcaaaatat ttcagctacg 5940 tacttgatgg ggtgccccga atgagagaga ggccaattgg ggatttggtt gctggtctta 6000 agcaacttgg tgcagatgtt gattgctttc ttggcacaaa ctgtccacct gttcgtgtaa 6060 atgggaaggg aggacttcct ggcggaaagg tatggtttgg atttcattta gaataaggtg 6120 gagtaacttt cctggatcaa aattctaatt taagaagcct ccctgttttc ctctctttag 6180 aataagacta agggtaggtt taggagttgg gttttggaga gaaatggaag ggagagcaat 6240 ttttttcttc ttctaataaa tattctttaa tttgatacat tttttaagta aaagaatata 6300 aagatagatt agcataactt aatgttttaa tcttttattt atttttataa atattatata 6360 cctgtctatt taaaaatcaa atatttgtcc tccattccct ttcccttcaa aacctcagtt 6420 ccaaatatac cgtagttgaa ttatattttg gaaggcctat tggttggaga cttttccttt 6480 tcagagatta tccctcacct ttattatagc ctttctattt ttaaacttca tatagacgcc 6540 attcttgttt taaaaaacac taagttttct tttagttata ccttcccctc cttattctct 6600 ccaaagtaaa tattgtagca agtgttggtt gatccattgt gaatcttatt atcctattta 6660 acatgcaggt gaaactgtct ggatcagtta gcagtcaata cttgactgct ttgcttatgg 6720 cagctccttt agctcttggt gatgtggaaa ttgagattgt tgataaactg atttctgttc 6780 catatgttga aatgactctg aagttgatgg agcgttttgg agtttctgtg gaacacagtg 6840 gtaattggga taggttcttg gtccatggag gtcaaaagta caagtaggtt tctatgtttt 6900 agtgttacat cacttttagt atccaaaatg caatgaaatt aaaactcatg tttcctatta 6960 ggtctcctgg caatgctttt gttgaaggtg atgcttcaag tgccagttat ttactagctg 7020 gtgcagcaat tactggtggg actatcactg ttaatggctg tggcacaagc agtttacagg 7080 tattcatgaa tgacactatc ttctattatc ttttatttta tagcttacac tatcattcct 7140 aattcaaccc ccttcttttc tctttcccct cactcccaaa atagagctta tcattgtatc 7200 cttaatagct cttttatgtg ctgtttcatc tcttgagcag attctacatg attatccttt 7260 ttagtgaact tttttgtctt ttaaataatt gatatcatca tttgaacttg cacatcatct 7320 ctatccttcc tcattttatt atatttcatt aagagtgata aaattacatt gtcaagtaaa 7380 gcaagttagc gtatcagata atgatgcttc gattgcagaa ttggtgaaag cttgcacaat 7440 tcattagctt agtgacaatt gtgatgtaga tagccataat cttccatgca acttattatg 7500 ctttttgtct aaaacttctt ttgcacttaa acatgaatta gagagttagg atgaacaata 7560 gtaacagaca caaagcttat ttctagacca cccagtggtg aagacgaagc agcatgagtg 7620 agattaatgg cagcatctga ttgaagcttc ttttggtatt attggagatg aaatcttgag 7680 ccaaattagg gcttttgcct cctcaatagc cattggttca aaattgcttt caataaaatg 7740 attacagaat caaattctta agaaagacct tcaagaacaa catcaagatg tttcctgtgc 7800 aaaacaggct cacctacaaa agagtgtcta caagcacctt tacacttgca aaaaattcct 7860 taactgaaca attgccaaga gtcatgttgc aaacttgaga ttggagttga ttagatttgg 7920 tgtgtgtgag attctggaaa tgagcatgaa gttttttgca aagctcataa aatgaatgca 7980 gccaagaatc ctagatagga ttgaatttga gagagaggct tgaagtcaag ataaccgcaa 8040 ctgatcttgc tgttcccatg ctgcatagga ctcgttgatt ctaccaagat aacaatcttc 8100 tgtggtgaga atatgagtgg gaattgtcag gcaacaaaga aaatgaaggc tatgagcctt 8160 tgttaaggtg cagagagaaa acagaaaatg aagaacttgt gtattgaagg aattgaaaag 8220 ccaattacaa ttgtgttgca gagagatatt tatagttctg aagtgtataa ctaactaaac 8280 agaatgctac caacctagag gcagttgaga attgctccct tattacaata ctctcacagc 8340 cttgatgata ggcttgattt gctgccaccg aagaagaaca ttattgttgg agagtttttc 8400 agtgattgca tcagagaaag ttacaagtgt gattggagat gaaggacttg cggtcgtcga 8460 aggttaagtg ttaagtggtg gaatgtgtat cggaggtggt tgcctagccc aagaagctgg 8520 ttgcagtgga agcggatgcg gcagaagcca tgggttcaga tcagaactat gttctagata 8580 ccatattagg gttagctttc aagagaaaac ttatgaaact gaactgtaaa ctgttgtatt 8640 attgattagc tgatctagta gtgatggaag cttgcttgcg aagcttctat ggaggctgga 8700 tcattgagct tcaatgaggt ccttcaatgg tgatttttca ccatggagat gcagcggaag 8760 ataaatgaag aggtgagagg aggcgtcatc cactaggaaa taaactatgg aagaaggagc 8820 ttcaccacca agagagtgtc ttggataaga agcttagaga ggaagcttca atggaggaat 8880 agaaagagag agggggaaca aaaaattgaa ggaggaaaag agggagagaa gttgaacttt 8940 gaagtgtgtc tcacaagact cattcattaa agttacaaca agtgttacac atgcttctat 9000 ttatagtcta ggtaacttcc ttgagaagct agaacttaac tacacacacc tctctaataa 9060 ctaagataac ctccttgaga aatttccttg agaagcttcc ttaagaagat tcctagagaa 9120 gctaaagctt agttacacac acctctctaa taactaagtt cacctccttg agatgagaag 9180 ctagagcctt agctacacac acccttataa tagctaaact cactctattc caaaatacat 9240 gaaaatacaa aaaagttcct actacaaaga ttactcaaaa tgtcctgaaa tacaagacta 9300 aaactctata ctactagaat ggtcaaaata caaggtccaa aagaaggaaa aacctattct 9360 aatatttaca aagagagtgg acccaacctt agtccatggg ctcagaaatc taccctgagg 9420 ttcatgggaa tcctagggtc ttctttagta gctctagtcc aattttcttg gagtcttcta 9480 tccaatatcc ttgggggtag gattgcatca tgtagtacaa gagaggggaa tatatataca 9540 gttgtaagtt gtaactacct aatcaaaccc aactgactca ccatacacag aaaaacaatg 9600 tacaaaggat aatagaaaaa ctgaaactga gatatactca ttacatagaa gaattacatg 9660 atgaatctga aaattttaat tgggaaactg aggacaataa caaggctttc agagttcatt 9720 ttgacaatag gtaaattatg gacttcaact tagacctcaa gggtatgctt gggagtgggg 9780 ttttagagga aaaggggaag gagggaaatt ttttaattct agtaaatatt ctctattttg 9840 attaattttt aaaataaaac aaataaactt atagattagc attcacttaa tgtcctgatc 9900 ttttatttgt ttcatgaagt tttttatagc ctttctgttt ctgttaaaag aaattggagg 9960 gtgttcataa tctatatgcc catatatatg tattgtcctg ttgtctgtgt ttctgttttc 10020 tttctttagt gtctcgcctt tccttaattc cttatcaaca ccttgtttat ttttgaaaac 10080 ttaaatgtcc tcattttttt tacctgtact ataactttcc aaacaaatag tagaaaatgt 10140 ttcaaatatt ccccagaact gtttcagtga acaaagttca agccagaaaa aaagcaagca 10200 gaggctaaag aagtatatct tattgtgaag agtaatctca attggttaat tatcgaattg 10260 tatcatttta caatagaaaa ttagaagtgg gttgattagt ttatacgaac aattatttaa 10320 atagggttga tggtgtggtt aattactgat catatgttaa gactatgagt cgatgaccag 10380 cctcagtgca gtcattttaa gttccattat tttttaattg tgcttatgtt taactttgtc 10440 cttcttttaa agggagatgt aaaatttgct gaagttcttg aaaagatggg agctaaggtt 10500 acatggtcag agaacagtgt cactgtttct ggaccaccac gagatttttc tggtcgaaaa 10560 gtcttgcgag gcattgatgt caatatgaac aagatgccag atgttgccat gacacttgct 10620 gttgttgcac tatttgctaa tggtcccact gctataagag atggtatggt ttagctgttt 10680 gtttttgctc aagagcttgt tttcacatat ttgtggtcaa gagcggttta gctgtttttt 10740 tttttaaatt gtggttaatg aaattattat aattatacta atattgaaat tggatcacta 10800 accatgtgaa atgcttgaat ttttagcttg aaaacttctt ttgtggatga tttttctttt 10860 atctatgtag tgtggggcat ctatgttgtt cctttaagct ttgtgtcata gttgtacaac 10920 ctggtctgtg ggctggtcca gttcttactc atgactgtct tttgcagcaa actggttaaa 10980 cttgggtgac ctgttgaccc acccagattg gcctgttctt ttttaaataa aactccaaaa 11040 ggctacttat aagatttcaa catgatactt gaatgaccac ccttacttta aaggtcatta 11100 tgccatcaga ccccttgatt ctctgttcag ttatgttctt attcttatta ttttttaatt 11160 tatattatta tccaacgatc tgatctttgt acatgatgct ggacaatcat caaagctagt 11220 ttggttacat catataatac cttttttttc ataaattatt ttttcccata atatatttat 11280 atgtattttt ttaatacaat attctgggga aatttttttt ttctgttttc ttttttctgg 11340 tttgaatact atttcaatga ctgggcctta ttattttctg gtttgggtta tacaactgtc 11400 ctttgatgta cttttgaatg cttcaatagt atttttcata atcatggaag gcactagagt 11460 gcagtgcata ttgcacaagg ttctttaatg gcatcttgaa tttgttagaa catggagtta 11520 tgatatacaa ccattcctat gtcttcatct aatagctaaa gcttttggcg tagttggtta 11580 acatggtatt ggaatcttat tttaaaggtc catcttattc gcaagtacaa ggcaggtgga 11640 cctgcgcatt attcacgtgc caggctcaaa gggattttgt atgaggggga atttttggaa 11700 tataatatat agaatcattc atgtggttca cctatcatgt gtcaactcaa gtttttgtcc 11760 tagttgtatt attgcagtgt ctaaactagg catgatcttc tgtggaagga aatttaacct 11820 aaggaacttg aatgcttctt gttctgagat ctttattttt tttctccaat ctttttaata 11880 cttgaaaggt tttagttgta tctataaagg gtgcagaatt agggggtcag cttttctgtt 11940 gtaagcgtga attaagtgca ttttatgttg ttccctattt tatacatttg aactatcaac 12000 catatcattt agcaaacttc tttgttgctc agattcccat ttattcttgt ttcctctatt 12060 ttttagtggc aagttggaga gttaaagaga ctgagaggat gatagcaatc tgcacagaac 12120 tcagaaaggt cttgctaatt cctttatggt ttctatatta ctggactttt tacatctcac 12180 tgacctacta ctgtcttggt atttcagcta ggagcaacag ttgaagaagg tcctgattac 12240 tgtgtgatta ctccacctga gaaattgaat gtcacagcta tagacacata tgatgaccac 12300 agaatggcca tggcattctc tcttgctgct tgtggggatg ttccagtaac catcaaggat 12360 cctggttgca ccaggaagac atttcctgac tactttgaag tccttgagag gttaacaaag 12420 cactaagcat tttgtacatt gagtagggaa gagagagaga tatatataaa tactcacaaa 12480 gcagtgagta tatggcttgc ttttgtttct aaacattcct ttataaggac ttgagataat 12540 ttgtattgtt taaaagagcc attggttctg ttgtatcaaa gtaatttaat tttcagtacc 12600 gacttggctc tactcatatg tggtggtgta cattgcatct ttgcatttga ttccatatct 12660 attgggatgg gaccatacat tttttgttta ttatttaagt caaacatatc agataatatg 12720 tggtgaccag aaaagtgtct agcaatcaaa tgggtctgtg attgcatgtt tgagttcagg 12780 acatttatta atgagtgaca gaattttaaa aagctcgcca ataggagttg ccacatctga 12840 tcgagtcttc tgtaaacact aactgtaact tgagtttgat aatcagattc cccccgttgg 12900 taggtaatat gtaaatttca ctatagattc ttactgagga tgatggtctt gacttcgaag 12960 tggtgagtgt aattctctaa tctaaacttt atatatatat aaaaaaagaa tgttaaaaac 13020 ttgagtgaca tacagcaaat agcaatgaaa gcatgaccat ggccttgggg ggccaaatgg 13080 ccatgtacca cttttccacc tacttgagag ccatggtcct gaatgaggtc cttttgtttc 13140 atttttttta caataaagaa agttcatatt cttggcaata gcaaggcaaa tcatttgtgg 13200 aagtcacatg aaattcacca taggcttcat tgttcaaatc ctttagtcac taaggcaggg 13260 cctatgtaag aattttgact actcttgtaa atgctgtgcg gtaaagacta cgggaaaata 13320 taaattattg catatctaga ggtgaggttc atttctccga tccatttctc caagtaataa 13380 aaatatatat aaattattaa tatggtatga tatggttatt tgtcctttaa atatgcgatt 13440 ataggttcaa tctttggtta atctatcaaa tgcatctcaa tattttgaga gaatagtttt 13500 tagctcttga ctgagagata ctttgagtta aaaaaatgta tttataaact attgtctatt 13560 gaatttttat tttttttgta acaccacatg tgagtatttt actaaatcca tgttacaatg 13620 tactgaatgt tttacaatac agtctggttt gataataaaa tatgcacaaa gtccagctta 13680 tgtaactctt tcaattcatg gaaaatgatg atatgcgaat tgaaagaaag aaaaccataa 13740 tgtaagtgta tttttttttt ctttctcttc tttaatatta ctcaatatca gattgcacat 13800 gggaagggta ctggctcatg tgggatatta atttttatcc cttacctaaa aagagagaaa 13860 gagaaaataa ctatttaaaa agagtaccac caccaccttt ttcgctttta agttttgttc 13920 tgttttcact actctttcat gcgttgtttg ttggcttccg atagtgacga atatgataat 13980 gattttacgt tgagaaaaaa aatgtgccat gtaaattcca gagattgaaa ttttagcttc 14040 aaattaatat ttattttatt atcttttcaa attggttgca tgtgaaagaa tttgaagttc 14100 ttcaacaagg aaataaacac ttcaatgctc aatccttaga gtcagtcact agatcccaaa 14160 agaatgtgat gtttacacac attagtatat atatatatat aaacacagct tatattatat 14220 taatgagtga tgcgcgagga cggtggtgac actacatggc caaaacaaga aatgtaattt 14280 aatttttttt tctttaagta ttactctatc cttgaatatt agtcttaaat cttcaaagac 14340 cttgcgaacg aagcaatctt gtcctgatcc tgtgattgtt ctacactagt ccttacgtgt 14400 acctaagcac atgatacttt gctgccctaa cataaattgt accataagga ttcttgggga 14460 gatgcttttg ccttcatttt caagtttgtt tacactttca agtcgttttt tcaatgcatt 14520 ctctttcctt tctgggaccc cttgtcttta acacgcgcgc acacaaaaac tagtagacaa 14580 taattagtac tacttgggtt ccattaaatt gtaactacat atacatgtgt tttttttttc 14640 ttggatcaac tgcatataca tatgttttat gagtttcatt gaatttatat ttacacaaac 14700 agttattaaa acataatgta gagccttgtc attaacctga tgttaggatt ataatttcat 14760 gctttgattt tgattgtacg ttttttgttt ttattgtaaa gtgtttattt tattaaaatt 14820 tgtcttggag tgctgtgatc tttagggtgc accgttcaaa agagagacga caaggataat 14880 actaatacta gtagattcca cgcattcaac cctagttagt ttagctatga caaattaagc 14940 atggtaagaa aaggggagga gaaaagtaag aatgaaaaca tataacaaat tgtgattgaa 15000 cttttccatg acgtaatgaa aacattaatt ttaagataag cttcaactcc taagaagaga 15060 tatgtcaaag aaacttagga ttttttctct atttataacg gtaaattact catcctttta 15120 aatgattaat ttgcgttgtt gaattcgttg taaagggaaa atcaagaagt ctcttcacgg 15180 gaaagttata tcaaagtatc atatactaga cttcatggct agcttttact ttgattataa 15240 gtaatgcatg caattaatgg gcaaataaat tatttgaaac caactaaagt acaaataatt 15300 ttcctccaaa acctctcaag ttcgcattga aattaaataa accaatgcat attaaggcgt 15360 aaatctaaac catgtttgtt tcatcttgta ttgtatatca tagtattaat aaggtacttt 15420 gaatttagtt gttattgacc gttaaattta ggggtgagtt gttttactat ctcttactca 15480 attgctttta ttcaacgcaa attctagtag gattttcagc ccaaattaaa agaagtttta 15540 cggtttgatt ctctacaaac ttgaattgag atttctaatt tcagaaatca ataattgcgg 15600 tcttaattaa ctctataatc aaacctttta acccaatctt tttctcaatt ctctgaatta 15660 agacaatcaa aatttaaact cacacgaatc tcacacgcct tcccacggta gagaaatata 15720 gggagtccct taatagcaaa agcctcaaaa ttcagaaaat ctcatccatt gcatttgcac 15780 attcaacaaa ccacccatta ttatgttccc ttaataaatc tcacacttaa aaaccctcct 15840 cacccataat taacccaaaa ggaagtttcc tccacacaaa aaatatcctt aaacaaagag 15900 cctctataaa tctattttaa aaaaaccccc aaatttaagg a 15941 32 15172 DNA Glycine max 32 aaaagtctga atgaagtgaa gttgttgtgt tagggggatg ctgaatttga ttttaattta 60 atttaaataa attacctgtg taaaggattt ttgtaccgcc ttttaatcac aaattgtcgt 120 gtatcgaaag tttgttgaat tttatagtaa ctatcttgga ggttatacct agtaggattt 180 ctgattagtt aaccatgtaa atttttttaa tgggtttgtg tttgttttaa ctgatgttgt 240 ttttgatatg tacgtggtaa gtgtgatgag tttgtgcata tcttgatcaa agactgaagt 300 gaagttgttg tgtttggggg gttgactctt ttaggaagag gatttgaggg aatttcgcca 360 atgggggagc agaactccgg gacaccctga gaattttgag actccgggaa ttgaagttac 420 aacaggtttg atatgagtta gagtttgtat aatagaatag taattctttt tattttttat 480 ttttattgtt tatttatcca ttattgctat ttttgtaggt cctcttggtc aggggattgc 540 caatgctgtt ggtttggccc ttgcagagaa gcacttggct gcaagataca acaagcctga 600 caatgagatt gttgaccatt acacgtaaaa ataactaaat catacacaac ttgcaagact 660 ttagttgttg gtgttttgct aatggcgttt gttttatgca ggtatgctat tctgggtgat 720 ggttgtcaaa tggagggaat tgcaaatgaa gcatgctcac ttgctggcca ctggggactg 780 gggaagctga tagcatttta tgatgacaat catatttcta ttgatggtaa cacagagatt 840 gcgttcaccg agagtgttga tagtcgtttt gagggacttg ggtggcatgt tatttgggta 900 aagaatggaa ataatggcta tgatgatatt cgtgctgcca ttaaggaagc aaaagctgtc 960 aaagacaaac ccacattaat caaggttagt ttactaattg tggcaatgat atgcatagat 1020 ttctggcttg tagttaccat aacaatcata atctgtcatg atttataggg attcttttaa 1080 actaaggtta taaacatgat atgttactaa agactgcatt gcattgtagt acctcatttg 1140 agaaactgga agttataggt gggaaatcaa aatagtaaat tatgggtcag tttattaagt 1200 gtagctggtt tgtcttttgc taactctatc atttcacagg tcacaacaac cattggttat 1260 ggttctccta acaaggctaa ctcctacagt gtgcatggaa gtgcactggg tgccaaagaa 1320 gttgatgcca ccaggcagaa ccttggatgg tcacatgagc cattccacgt gcctgaggat 1380 gtcaaaaagt atggatgatg ggtttagaga tttctttttt cctgtgacac tgctgatgtt 1440 tataatgata ctgaataaga attgcttgtc tgtccccagg cattggagtc gccacacccc 1500 tgagggtgct gcacttgaag ctgagtggaa tgctaagttt gctgagtatg aaaagaaata 1560 caaggaggaa gctgcagaat tgaaatctat tatcaatggt gaattccctg ctggttggga 1620 gaaagcactt ccggtgagta aattctaaac tcacaggttt ttcttacatg tttgtaactt 1680 ttcaaggttt ggattacata ctatccaaag ttgatcatga tttcagtttg atttggtagt 1740 atggggcttc aaaaagttat tccaaatatt aaaacctggc ttccaatttg atttcagaca 1800 tacactccag agagcccagc ggatgccacc agaaacctgt ctcaaacaaa ccttaatgcc 1860 cttgcaaagg ttcttcccgg tctgcttggt ggcagtgcag atcttgcttc ttccaacatg 1920 accttgctca aaatgttcgg ggacttccaa aaggatactc cagcagagcg taatgttaga 1980 ttcggtgtta gagaacacgg aatgggagct atctgcaacg gcattgctct tcacagccct 2040 ggactgattc catattgtgc aaccttcttt gtattcactg actacatgag aggtgccata 2100 aggctttctg cgctgtctga ggctggggtt atttatgtca tgacccatga ttcaatagga 2160 cttggagaag atgggccaac ccaccagcct attgagcacc tagcaagctt ccgggcaatg 2220 ccaaacattt tgatgcttcg tcctgccgac ggtaacsgaa acagccsgag catacaaagt 2280 ggccgtgctc aacaggaaag agaccctcca ttcttgccct atccaggcaa aaactgcccc 2340 agcttcccgg aactthcatt gaaggagttg aaaagggtgg ttacaccatt tcgggacaac 2400 tccactggca acaagcctga tgtcattttg atcggaactg gttcggaatt ggaaatcgct 2460 gccaaagctg ctgatgacct aaggaaggaa gggaaggctg ttagagttgt ttcccttgtt 2520 tcttggggaa ctttttgatg agcaatcaga agcstacaag gagagtgttt tccctgctgc 2580 tgtttcagcc agagttagca ttgaggcagg atcaacattt gggtgggaga aaattgttgg 2640 agcaaaggga aaagcaatag gcattgatcg ttttggagct agtgctccag ctggaagaat 2700 atacaaagaa tttggtatca ctaaggaagc tgttgttgct gcagctaaag agcttatcta 2760 gaacttttga tttttttttg ccttctggtt ttggttgaga gcattccatg tcatgaataa 2820 gaaaaaggtt aaatatcctt cgattgggaa tttgggattc taagtgaaga agcaacatag 2880 atcaaagaat tttgtgaact tgtaataact atttgacaat ttagttttgc actgccacat 2940 ggttaaattc aatgtttgat catatcaacc atagatgcta gtttatacta cttgtataat 3000 ttgtttcact tgcagattca ctcttagcat ttgagtgttt ggatggccgt gttttgttca 3060 ttaagaaatg ttgacatgga tagtttgttg catggtaaat tggtgattaa taccttttta 3120 agcttctttt ggcaagttgt taaaaagtgt tttgttttaa tctctagtta atctaaaaat 3180 gcctacttat tttattttga ctttcaaaac ttgtctatat gccgagtata aaaaaaactt 3240 gtctatataa gttccttatg gaaaaaggac ctacaaaata atttaaaaat gctgaatttg 3300 ttaggaagtt tgacaacttt agacattaat aattgttttt ttttcatata tataattgac 3360 tttcaaaact tgtctatata ttataaattc gttatggaaa gggcgaccac acgtaaaacg 3420 taacatgcca atctctccct agtgaactgt tattctcatt cagtttttgt aagttcacct 3480 tcaaattttc aatttttttt ttgacaaaaa tatctttgat ggaacacgtt aggggtgtaa 3540 attcaccatt catcatttca ttcattatac acaatagtct ttcataatcc aatgaaaact 3600 tgtttttgtt gttatttttt tctgaaaaat ctttataaaa taaataaaaa catttttttg 3660 ttataaattt cagttgaaat acataaccat taattctaca gagtgttaat gttgatgtaa 3720 aataaaaaaa tattggatat caaacttaat gaacagaaca aaaattacaa aattgtacaa 3780 tttaaatgat aaaaaaccaa attcacaaaa ataaaaatta aggacgaaat ttgagaaatg 3840 ataattaaaa acgattaaaa atataattaa actaaaattt attatgtaat tctttaatat 3900 atatatatat atatatatat atatatatat atatatatat ataataaaag ttttacatta 3960 taattttgaa atgaagtatt tgataaacga acaacccacc cttggggttg gtgagagtga 4020 aacggagaac agtgtctccc tcacttggtc ttctgagtcg agtcctattc atcaccaacc 4080 cactcgtcaa aattgttgta tgctatgtaa ccattttgtt ttttaataaa taaaagtgtt 4140 ttgttctgct atgcactccc catcaaatac catttacttt ttttttgtct tctatcaatt 4200 tctatttagt tcctagttgc tacaacttcc agctggtgaa aaatagtcaa cagagactac 4260 aatattctaa taaaatagaa taacaaaatc aaatatattc atttaatatg attttatttt 4320 tatttaattt aaaacatgaa ttatttgttt cttatttaat taccgtttcg ttcacttctc 4380 aattaataaa ataaaaaatt tctacaatta tagaaaaagt ttagttttgt agattgttaa 4440 cataaagatt tttcctatta actaattaat taaaagtcat cttatatata agttttaaag 4500 taattatctt atatatgtac ccaaaagttt taaagcaatt attataaaaa agtaaaattt 4560 tatcatatac aataatctat aattacatga aagtataatt tttaaattat taatacgtta 4620 aaattatttt tttaaaattt gaatgatcat atagtaattt tattttatac caagtcccaa 4680 catttcctat tttattccac ttttaccaat aaatttcctc ataaacactt ataagaaaaa 4740 aagtaagtaa agaataaaat aagcttttct ataaactata aacaaatttg tataaacttt 4800 cttatattag tttttctgaa aactaatttt aaattataca taaattgaat ttactgataa 4860 ttttttattt tctttttgta taagtgtttt ttaagaaatt tgttcaaaca tatttttatg 4920 acatgtcaat gcttgagaga tataaggtga gttaaatcat aaatgattaa agaaaaataa 4980 aagaagaaaa agataattaa tttaattttt tattaacatt ctaacaaatt aacattatat 5040 aaataaaaat aatatttcaa taattggatc aataatacta ttgttcttaa acaccaaacc 5100 aaccttccta aagtcctaat ctaatccaaa agccatcatt cattttcctt ggtaggtaaa 5160 gttccaaaac ctttaccaac cttttcactc aattattttg gtgtaagcaa ttcgacatgt 5220 gttagtgtta gttggcaacc aaaaacccct ttatgtgact cactcaatcc aacaacctct 5280 cacaccacca acccccccat aactcataag gccaaaacca tttctcacaa aacccttcat 5340 tacacacatt attatcatta tcacacacac aaaaaacctc tcatttcaaa gagagagaga 5400 gatttcacag accaaattgc agaggacgac aaagttcaca acttcaagga aaatcgaaat 5460 ggcccaagtg agcagagtgc acaatcttgc tcaaagcact caaattttyg gycattcttc 5520 caayyccaac aaacycaaat cggygaattc ggtttcattg aggccacgcc tttggggksc 5580 ctcaaaatct cgcatcyygr tgmayaaaam tggaagcytt atgggaaatt ttaatgyggg 5640 gaagggaaat tccggcrtgt ttaaggtttc tgcatcsgtc gccgccgccg cagagaagcc 5700 gtcaacgtcg ccggagatcg tgttggaacc catcaaagac ttctcgggta ccatcacatt 5760 gccagggtcy aagtctctgt ccaatcgaat tttgcttctt gctgctctct ctgaggtaaa 5820 gtttatttat ttatttattt ctgtatccaa aaatgtaaat tgttagtttg ttaatttttg 5880 ttagcagtga gagtcgaact acttggcttc tttcttagtc atccaaccaa ccttatatct 5940 ccaaaattta tttattggtt ttttttgggg ttatgtggtt aggaatagga gtttgatgcg 6000 tggagtggat tttgaatatt tgattttttt tttttttgta ttattcagtg aaaatgaagc 6060 atcttgtccc atgaaagaaa tggacacgaa attaagtggc gtatgattta gaatgatgat 6120 agaaatgtgt ataggtggtt ttaatgtgta gcaataagca tattcaatat ctggattgat 6180 ttggacgttt ctgtataaag gagtatgcta gcaatgtgtt aataatgtct tgttaaaagt 6240 atggatggct aaaataatca taaaaatcga gtgggagtag tatacatatc tacaggaaat 6300 gtattaggtg aggcatttgg cttctctatt gcgagtaagg aacaagtaat ctcagttaat 6360 gtgaaaatca atggttgata ttccaataca ttcatgatgt gttatttacg ggaacgcaat 6420 attgactgtt gattttatct gcagctgaga ttatatacta tatccttcca aagaaatctt 6480 tgactcttga ttatccaagt atggttgtat taccaatttt agctctagaa gataatccct 6540 cccccaaaac acaaattaga atggtgctgc aagttccgtg ttactttcat tctattattt 6600 ttataacttt taattattta atagatgtct tgtttggcat aaactataat ttattctgtt 6660 tttttttatt cttatttagg gaacaactgt tgtagacaac ttgytgtaya gygaggatat 6720 tcattacatg cttggtgcat taaggaccct tggactgcgt gtggaagayg acmaaacaac 6780 caaacaagca attgtkgaag gctgtggggg attgtttccc actaktaarg aatctaaaga 6840 tgaaatcaat ttattccttg gaaatgctgg tactgcratg cgtcctttga cagcagctgt 6900 rgttgctgca ggtggaaatg caaggtctgt tttttgtttt gtttgttcat catgatctct 6960 gaattgttcc tcgtataact aatcacatca gactatgtgt tcttcctcca tcctgttata 7020 atctaaaaat ctcatccaga ttagtcatcc ttctttaaat gaacctttaa ttatatctat 7080 gtatttattt aacatgtaaa ttagcttgtc aagtcaaagt ctagcatata gatatactga 7140 ttacactctg aggaatgcac ctgagggtct taatcatgat ctatttcaac cttgccactt 7200 tcttctttta ttattagatc acctatcatg attactggtt tgagtctcta aatagaccat 7260 cttgatgttc aaaatatttc agctacgtac ttgatggrgt gccccgaatg agagagaggc 7320 caattgggga tttggttgct ggtcttaagc arctyggtgc agatgttgat tgctttcttg 7380 gcacaaactg tccacctgtt cgtgtaaatg ggaagggagg acttcctggc ggaaaggtat 7440 ggtttggatt tccattagaa taaggtggac taactttcct ggagcaaaat tctaatttat 7500 accctgtttc cccctcttta gaataagaca ctaagggtat gtttaggagt tgggttttgg 7560 cgagaaaggg aagggagggc aatttttttt ctaataaata ttctttaatt tgataaattt 7620 tttaaacgaa ggaatatgaa gatagattag cataacttaa tgttttaatc ttttatttat 7680 ttttataaat attatatacc tctatttaaa aacaagatat ttttcctcca ttccctttcc 7740 ctttaaaacc tcagttccaa atataccgta cttgaattat attttggaag gtgtattggt 7800 tggagacctt tccttttcag aggttatccc tcacctttat tatagccttt ctactctctt 7860 aatgagttca ttgtgcattg agtcattgaa cttcctgtga aaagaaattg tttacttttc 7920 tttatttgtt acctacatcc ttattcctgt tttaaaaaat actaagtttt cttttagtta 7980 tgccttcccc tccttattct ctccaaagaa aatataatag cgaatgttgg tttatccatt 8040 gtgaatctta ttatcctatt tcacatgcag gtgaaactgt ctggatcagt tagcagtcaa 8100 tacytractg ctttgcttat ggcagctcct ttagctcttg gygatgtgga aattgagatt 8160 gttgataaac tgatttctgt tccatatgtt gaaatgactc tgaagttgat ggagcgtttt 8220 ggagtttctg tggaacacag tggtaattgg gatargttct tggtccatgg aggtcaaaag 8280 tacaagtagg tttctatgtt ttagcattac atcacttttt agtatccaaa atgcaatgaa 8340 atcaaaactc atgttttcta tcaggtctcc tggcaatgct tttgttgaag gtgatgcttc 8400 aagtgccagt tayttmctag ctggtgcagc arttactggt gggactatca ctgttaatgg 8460 ctgtggcaca agcagtttac aggtattcat gcttgacact attttctatt atcttttatt 8520 ttatggtcta tactgtatca ttcctaattc aacccccttc ttttctcttt cccctcactt 8580 ccaaaaaaat agagcttatc attgtattct taatagctct tgtatgtcct ttttcgtctc 8640 ttgagcagat tctaccgtga ttatcctttt tagtaaactt tttttttgtg tgtcttttaa 8700 ataattgata tcatcatatg aattcacaca tcatctctat cccttcctca ttttattata 8760 tttcattaac agtgataaag ataaaaataa attgtcaagt aaagcaagtt agcatgtcag 8820 ataatgatgc ttcaattgca aaattggtga aagcttgcac agtacattag ctttggtgac 8880 aattgtgatg tagatagcca taacctccca tgcaacttat tatgttgttt gcttaaactt 8940 cttttgcact taaacacgga ttagagagag tgaggatgaa caataataac agacacaaag 9000 cttagtttta taccacccgg cacccagtgg tgaagaccaa gcagtatgag tgagatcaat 9060 ggcagcatct gattgaagct tcttgtggta tttttggaga tgaaatccga ggcgaattag 9120 ggcatctggc tcaacaatag ccattggttc aaacttgctt ttaataaaat tgattacaga 9180 atcaaattct tgaggaagcc ttcaagaact acatcatgat gttccctgtg caaaacaggt 9240 tcaccgacaa aagagaacat ctacaagttc ctttacacat gccaaaaatt cctcaactga 9300 acaattgcca agagtcatgt tgcgaacttc aggttggagt tgacgaaatt tggtgcatgt 9360 atgattctgg aaatgagcat gaagtttttt cctaagctca taaaagtgaa tgcagccaag 9420 aaccctagat aggattgaat cggagagagg cttgaagcca agataacagc aactgatctt 9480 gctgttccca tgctgcgtag gactcattga ttctaccaag atcacaatct tctgtggtga 9540 gaaaatgagg gtgaattgtc aaccaataaa gaaaatggtg aaggctgagt cttgatgata 9600 ggcttgattt gcttgcgctg aagaagaacg ttattgttgt agagtttctc agtgattgta 9660 tgagagtaag ttacaggtgc gattggagat gacggacttg tggtgggagg agggtaagtg 9720 ttaagtggtg gaatgcgtat cagaggtggt tgcccagcca aagaagctgg ttgcggtgga 9780 ggaggtggtg gtgcagtgga agccatgggt tttgatgctt ttgagagaaa acatacgaaa 9840 ctgaactgta aacttttgta ttattgatta gctgatttgg tagtacaaga gaggaatata 9900 tatacagttt taatgtaact acctaaccaa acatgaggaa ctctccatac acagaaagac 9960 gtatacaaag gataacagac aaacagaaac ttagatatac tcatacagag aagaattaca 10020 ggatgaatct gagaatttta attgggaaac tgaggaaaat agcaagggtt tcagaattca 10080 ttttgacgat aggcaaatca tggacttaac ttagacctca agggtacgct tgggagtggg 10140 ggtttttaga gggaaaaggg aaggagggca aacttttaat tcctaataaa tattctcttt 10200 tttgattttt ttttaaataa aacaaataaa cttatagatt agcatacact taatgtccta 10260 atcttttatt tatttgcatg agtttttttc ttttatattc tttctgtttc tgttttcttt 10320 cttcagtgtc tcttgtcttt ccttaattcc ttatcaatac cttgtttatt tttgaaaact 10380 taattttcct cattttttta acttataggc tatactatag tatgtataac tattcaaata 10440 aatagtagaa aatgtttcaa atattcccca gaactgtttc agtgaacaaa gttcaagcca 10500 gaaaaaagaa gtatatcttc ttgtgaagag tagtctcaag tggttaattg tcaaattgta 10560 tcattttaga atacaaaatt agaagtggtt tgattagttt atacgaacga ttatttaaat 10620 agggttgatg atgtggttaa ttactgatca tatgtgaaga ctgtgagtcg atgaccagcc 10680 cagtgcagtc attttaaatt ccattatttt ttaatttgtg cttatgttaa actttgtcct 10740 tctttcaaag ggagatgtaa aatttgctga agttcttgaa aagatgggag ctaaggttac 10800 atggtcagag aacagtgtca cygttwctgg accrccacra gattyttctg gtcraaaagt 10860 cttgcraggc attgatgtca atatgaacaa gatgccagat gttgccatga cwcttgcygt 10920 tgtygcacta tttgctaatg gtcmmactrc yatmagagat ggtatggttt agctgtttgt 10980 ttgtgttcaa gagcttgttt taacaaattg ttttttttaa ttatggttaa tgaaattatt 11040 ataattacac taatattgaa attggatcac taaccatgtg aaatgcttga atttttagct 11100 tgaaaacttc ttttgtggac aatttttctt ttatctatgg attgtggggc atctatgttg 11160 ttcctttaag cttcgtacaa cctggtctgt gggctggtcc agtccttctt actcatgaca 11220 gtcttttgca gtaaactggt taaacttggg tgacctgttg acccacccag attggcctgt 11280 tctttttaaa taaaacttgg ctacttataa gatttcaaca tgatacttga atgatcaccc 11340 ttactctaaa ggccattatc tgttcagtta tgttcttctt cttcttatta tttttaattt 11400 atattattat ccaacgatct gatctttgaa catgatgctg gacaatcatc aaagctagtt 11460 tggttacatc atataatacc ttttttttca tatattattt ttcccatagt atatttttgt 11520 gttttttttt catacaatat tattctgaaa aaaacttgtt tcgttttttt cctggcttga 11580 atgctatttc aatgactggg ccttattatt ttctggttta ggttatacaa ctgtcctcca 11640 attgactttt gaatgcttca atagttttct tcttaatcat ggaaggcact agagtgcata 11700 ttgaatatgt tagaacatgg aaggcttaaa tatcttttta gtctttgcaa tttaacgttt 11760 ttttgctttt agtccttgca aaattataat ttttttttag tcctgactaa ttatgtttgt 11820 tttgtttttg agggcgagcc ctggtgcagc ggtaaagttg tgccttggtg acttgttggt 11880 catgggttcg aatccggaaa cagcctcttt gcatatgcaa gggtaaggct gcgtacaata 11940 tccctccccc ataccttcgc atagcgaaga gcctctgggc aatggggtag aaaaagaaga 12000 atgctttaga taacactttt tttgttactg ttcaaagcac tatctaaagt gctttgagga 12060 ctaaacacaa aacaaacata atttgcaagg actgaaaaac aaaaaaataa ttttgcaagg 12120 acaaaaaaac aaaaaaaaaa aacaaaattg caaggaccaa aaatatattt aaaccaacat 12180 gaaattatgg tataaaacca ttcatatgtc ttcatctaat agcttaagct tttgggatag 12240 ttggttaaca atatggtatt agagtcttat gatttttagg tggtctttga gttcaatcct 12300 tgctgctccc agttctagtt aatttctttt tggtccactt caaataaaaa gttgaattta 12360 agggtaaggc agctggacct gcgcattaat catgtgtcag gctcaaaggg cttttgtatg 12420 gggggcatgt ttggaatata atatagaatc attcatgtgg tttcacctat caaggacaac 12480 tctagttttt gtcatacttg tattattaca gtgtctaaac tagacatgat ctttttccgg 12540 aaggaaattt aacttaaaag gaacttagat gcttcttgtt ctgtgatctt tatttgttta 12600 ttttttccaa tctttttaac aattgaaagg ttttagttgt atccaatctt tttatacatt 12660 tggactatct accatatcat ttagcaaact tgtttgctgc tcagattctc ctttggacta 12720 tctaccatat catttagcaa acctgttcac tgctcagatt ctcatttatt ctttgtttcc 12780 tctatttttc agtggcaagt tggagagtta aagagactga gaggatgata gcaatctgca 12840 cagaactcag aaaggtgagt gtcttgctaa ttcctttatg gtttcgatat tactggactt 12900 tttacatctc actgacctac tctgtcttgg tatttcagct aggagcaaca gttgaagaag 12960 gtcctgatta ctgtgtgatt actccacctg agaaattgaa tgtcacagct atagacacat 13020 atgatgacca cagaatggcc atggcattct ctcttgctgc ttgtggggat gttccagtaa 13080 ccatcaagga tcctggttgc accaggaaga catttccyga ctactttgaa gtccttgaga 13140 ggttmacaaa gcactaagca ttttgtacat tgagtaggaa gagagagaga gataaatact 13200 cacaaaacag tgagtatatg catggcttgc ttttgtttct taacattccc ttgtaagaac 13260 ttgagataat ttgtattgtt ggaaagagct attgattctg ttgtatcaaa gtaatttaat 13320 ttccagtaca gacttggctc tattcctcat atgtggtggt gtacattgca tctttgcatt 13380 tgatcccatt tctattggga taggaccata cctttttttg tttattattc aagtcaaact 13440 tagcagataa tatgtggtga ccagaaaata gtctagctag caaatagacc tgtgattgca 13500 tgtttgaatt caggacttca ggacatttaa ttaatgagtg acaatgttaa aaagctcgcc 13560 aacaggagtt gacacatctg attgagtctt ctattaacac taactgtaac ttgagtttga 13620 ttatcagatt cctcctgttg gtaggtaata tgtaaatttc actatatatt taccgaggtt 13680 ggtggtctta cttgactttg aagaggtgag tgtaatttaa acttttatat caaaaaaaga 13740 ttgctaaaag cttgagtggc atgcaacaaa tagcaatgaa agaatgacta tggccttggg 13800 aaccaaatgg ccacgtacca cttttccacc aacttgagag ccctggtcct ggatgatgcc 13860 cctttttttt tttcatttct ttgacaataa agaaagttct tattcttggc aattgcaagt 13920 cgtttgtgga agtcacatga aattcaccat aggcttcatt gttcaaatcc tttagtcact 13980 aactaaaggc tggacctatg caagaatttt ggctactctt ataaatgctg tgcggcaaag 14040 actacggaaa aatataaatt attgcatatc tagaggtgag gttcattgct cccatccatt 14100 tttccaagaa ctaaaatata tataaattat taatatgata ttacattgaa aaataatatt 14160 tttcttttaa atatgtgatc ataagtttaa ttttaagtct attcatacga aaaaaatatt 14220 tattagaaaa gattaattta ttaaatggat ctcaatattt taagaaatta acttttagct 14280 ctcaaccaac agatgatttg agttaaaaaa atgtatatat aaactattgc atatctgctg 14340 atttttgttt gtaacaccaa taagtgggca ttttactaaa tccatgtgac aatgtactga 14400 atgttttaga atacagtctg gtttgataat aaaacgtgca taaagtccag cttatgttaa 14460 ctcttaattc atggaaaatg atgatatgcg aattgaaaga aagaaaacca taatgtaagt 14520 gcagttttct ctctcttttt taatattatt caatatcaga ttgcacatgg gaaggggtat 14580 tggctcatgt gggatattag tttttgtccc ttacctaaaa agagagaaag agaaaaataa 14640 caatttaaaa agagtaccac cgctaccacc tttttcgctt ttaaattttt gttctgtttt 14700 cactactctt tcatgcgttg tttgttggct tctgatagtg acgaatatga tataatgatt 14760 ttatgttggg aaaaaagtgc catgtaaatt ctagagattg aaattttagc atcaaattat 14820 ttattttatc accttttaaa atttgttgca tgtgaaagaa tttgaagctc tccaacaagg 14880 aaataacact tcaatcctta gagtcatcct ctagatccca aaagaatgtg atgtttatac 14940 acattagtat atatatatat atatatatat atatatatat atatatatat atatatatat 15000 atatatatat agggtttata ttatattaat gagtgatgta cgaggacggt ggtgacacta 15060 tatggccaaa acaagtgtaa tataattatt tttttttctc aagtattact ctatccttga 15120 atattattag tcttaaatct tcaagcacct tgtgaacgaa gcaatcttgt cc 15172 33 32 DNA Artificial Sequence Primer 33 gcacarcgag caagagaraa agccatagcc at 32 34 29 DNA Artificial sequence Primer 34 gcwggaacwg cmatgcgacc rytaacagc 29 35 15941 DNA Glycine maximus 35 aaaaaatacc ttttagtaaa ataagagcgt ragatcaatc agacgttttc tctttgggac 60 ttctcattct taattgaatt gacaataact aaagtgaaac taaggctaaa atcaactcgc 120 ctagtcaagc tcgtccacaa aaataggttt ttgaaagttt accatgtcag tttcttacta 180 agtaaaaaag gatcatttgt aaggtccaac gccttaaaat gatcaccctt caaagtaaaa 240 gaatcacttg tttcacgcat aagtaagaac tacgtaggtc tgatttcctc tccaaaggag 300 ggtacgtagg agcaaaagcc ccgcttttgt cgaccttaaa aaataaaaag aaacaaaagt 360 taaggtaaca caatttccac aattctagaa ataaggttgt tgtctttcga gacaaacgta 420 agaggtgcta ataccttcct caaacgtaaa tacaactccc gaacttagaa ttttcatttt 480 gaccggtttc cttcggtttt cccgacgttt tccacaaata aacgttggtg gcgactccgc 540 gcatctttcc tcctttggaa agcgcaccca tgagcctcgc cctcgctcgc ccgcgaaggg 600 cacgttgcga cactaggtta ataagaagtt tagtccacat atctatggac ctcttaaggt 660 gattatcaaa gtggaagtgg tgacctacat gttggcccta ccagcttatt cgtatattta 720 cccccatcaa ccatgtatct cagctgaaac atgctatcaa tccaaatgtt atcagaggaa 780 catgagctgc atgttcaacc agaagtagtt ctagtcttaa tacaaatgtc aaatggcaca 840 agtgagattt tgaatttctg atgttgtaaa aatctcagga catgaatact attgggaagc 900 aattattcat acttcaccaa tccaaactga cccaaaattc tcaaatcaca tgaaagcaaa 960 aatgcatata acacgaagaa taagaagaag aggaactaac ctggggtttc gatgattaaa 1020 gcgttgttgt tgatgatgaa aacgatgatt atggagagaa attgttgttg aatggtgaaa 1080 ttgttataga aagagaacga agatagagaa aaagatatat agatttttca aggctcaaac 1140 cctaaaatca ccatgagaga gaacaaagat tgagaaacct acaaccacta tgagagagaa 1200 tgagcagaac agaagcgtga gatagagaac gagagttaag gtgcgagagg acacgaagaa 1260 caaaaggtgt gagagaaaga acaaaggagc ctacggtgtg agatgagaga atttgaaatt 1320 cttaccattt aggtggaatt tcaattctac aattttattc tattaaaatt attttaaaaa 1380 atgatgtcat tttaaattct ttaaaatctc atatccaaca actgaattat gatagaggta 1440 tttcaaattc acttaaaaaa attatcttat ttaaataccc catccaaaca tagcgaaatg 1500 ttcatgagaa ggatcaagtg gtttggaaac atagtactaa tggtgtttat acagttcatg 1560 gaatccttga tagataattt aaaggttgct ggaaattgga tgaaggtgtg gagattaaat 1620 attcttccaa aaataaagcg ttttatttgg agagtgttgt gtggttgtct cccctgtagg 1680 caaaagcttc gatgtaaagg agttcaatgt ccaataacct atgctttcta tccctcgatt 1740 attgaaaatg aatgacacat tttatttggt tgaaatcaag aaataagcat gtggcaagca 1800 acgggtattt gacaattcat agaacaaaag gtgaatgcag caaaagaatt aatgaactcc 1860 ttttcgatct acttggatca ctacatggag atattatcaa caaatttgat gttactttat 1920 ggagcagttg gaattcttgg aatgacaaga tatgaaatga acataccaac cctcctcttg 1980 tttctgtttc ggtttctatg cagtattttg ttgaatggca aagtgcaagg taatatgctc 2040 ctcaacatca attaacaaat gttcatgaca tctcttacca gctccaactt ggggacgttt 2100 gacaaacacc accgtcaagt ttccttaaat gcaacattaa tgttgctcat ttcaaggagg 2160 agaatagttt tggtgtcggc atgatactcc atcaaggaag attcgtcaaa gctcactcac 2220 gttttcgaca tgggtcgaca tgggttacct gacccaaagg ctgaggctta ggcttgggtt 2280 tgcttcaagt attgatctgg gcccagacta ttggtttaca taatatcatt tttgaaaacc 2340 taacatctaa aactcaaggt tgtttagagg tgcgccattc caaaataaga ttatcctatt 2400 tgtgcatgaa tgcgaccaac tatctcctgt ttcagcatta taaagtataa acaacaaact 2460 tctttaatca agggactaaa agatattgga catacaagct aaaagtgata gaatttgaga 2520 aaacaaatat tgacaacaat attcaagagg acactaaaac ataattctca aatttttttt 2580 gtttatttaa aataaagtgg ttcattaggt agctcttgaa aaaaaaaagt gattaacatg 2640 ctagtacatg ttaaaaaaag tgaataatat tctattataa gtaaagagga ataatttatc 2700 gatgtctcat ttttgagata gttcaccgaa gccaattttt ttactttttt ctcttcaatc 2760 aattttattt tgttaatagt tgtcattgtg gatggattat aataattttg aaatgattta 2820 aaatgagata tatattaata aatttaatta attcataaat atgttactaa atataaattt 2880 catggtatac tcaggacggt tataacggaa atcaaataaa taataaaata gaataatatt 2940 aatttgcagt aaaaagaata atattaattt attctgttta cactatgtat aacgaaatta 3000 aatatattca tttaatatga ttttattttt ctttaattta aaaacatgaa ttatttgttt 3060 cttattttat taccattttg ttcacttctc aattaataaa ataaaaatat attctacaat 3120 tatagtaaaa aggtttaatt ttatataatg ttagcataca gatttttctc tattaactaa 3180 ttaattaaaa attatcctta ttttaaggaa attaaaaatt atcatatata tataagtttt 3240 aaattaatta tcttatatat gtaccaaaaa gttttaaagc aattattata aaaattaata 3300 aatttatcat ataaaataat ttataattaa attttaaatt atcaattcat taaattaaat 3360 tatttaaaat ttttgaatga taatataata attttatcct ctactaagtc ccaacgtttc 3420 ctattttatt ccacttttag caataaattt tgtcataaac acttataaca aaaaaagtaa 3480 gtaaaaaata aaaaaaagtt tttcaataaa gtataaacta atttgtataa acttttagaa 3540 aaaataaagt tatacattga taatataaat tttttacata attatccgat caactcatta 3600 tatatgataa atttattgat tttttaaaat aattatctta aaataattta aacaatgatt 3660 tgcaattaga tgataatata aaattatttt acacactaca tgtattaaac tcaaactttt 3720 atatattagt ttttctaaaa actaattttt aactcaaaaa aaatgttact tataattttc 3780 ttatcttctt tttttataag tattttttaa gaaatttatt gaaacatgac catgcttggg 3840 tcaataatac tactctctta gacaccaaac aacccttccc aaactataat ctaatccaaa 3900 agccatcatt cattttcctt ggtaggtaaa gttccaagac cttcaccaac tttttcactc 3960 aattgttttg gtgtaagcaa ttcgacatgt gttagtgtta gttggcaacc aaaaatccct 4020 ttatgtgact caatccaaca accactcaca ccaccaaccc ccataaccat ttctcacaat 4080 acccttcatt tacacattat catcaccaaa aataaataaa aaaaacctct catttcagag 4140 agagagagag agacttcaca gaccaaagtg cagagaacaa caaagttcac aactttaagg 4200 aaaattgaaa tggcccaagt gagcagagtg cacaatcttg ctcaaagcac tcaaattttt 4260 ggccattctt ccaactccaa caaactcaaa tcggtgaatt cggtttcatt gaggccacgc 4320 ctttgggggg cctcaaaatc tcgcatcccg atgcataaaa atggaagctt tatgggaaat 4380 tttaatgtgg ggaagggaaa ttccggcgtg tttaaggttt ctgcatcggt cgccgccgca 4440 gagaagccgt caacgtcgcc ggagatcgtg ttggaaccca tcaaagactt ctcgggtacc 4500 atcacattgc cagggtccaa gtctctgtcc aatcgaattt tgcttcttgc tgctctctct 4560 gaggtgaagt ttatttattt atttatttgt ttgtttgttg ttgggtgtgg gaataggagt 4620 ttgatgtgta gagtggattt tgaatatttg attttttttt gtattattct gtgaaaatga 4680 agcatcatgt cccatgaaag aaatggacac gaaattaagt ggcttatgat gtgaaatgag 4740 gatagaaatg tgtgtagggt tttttaatgg gtagcaataa gcatattcaa tatctggatt 4800 gatttggacg tttctgtata aaggagtatg ctagcaatgt gttaatgtat ggcttgctaa 4860 aatactccta aaaatcaagt gggagtagta tacatatcta cagcaaatgt attaggtgag 4920 gcatttggct tctctattgt aaggaacaaa taatatcagt taatgtgaaa atcaatggtt 4980 gatattccaa tacattcatg atgtgttatt tatatgtacc taatattgac tgttgttttt 5040 ctccgcaatg accaagatta tttattttat cctctaaagt gactaattga gttgcttact 5100 ttagagaagt tggacccatt aggtgagagc gtggggggaa ctaatcttga atatacaatc 5160 tgagtcttga ttatccaagt atggttgtat gaacaatgtt agctctagaa gataaaccct 5220 cccccaaaac acaaattaga atgacatttc aagttccatg tatgtcactt tcattctatt 5280 atttttacaa cttttagtta cttaacagat gtcttgttca gcataaatta taatttattc 5340 tgtttttttt tagggaacaa ctgttgtaga caacttgttg tatagtgagg atattcatta 5400 catgcttggt gcattaagga cccttggact gcgtgtggaa gatgacaaaa caaccaaaca 5460 agcaattgtt gaaggctgtg ggggattgtt tcccactagt aaggaatcta aagatgaaat 5520 caatttattc cttggaaatg ctggtactgc aatgcgtcct ttgacagcag ctgtggttgc 5580 tgcaggtgga aatgcaaggt ctgttttttt ttttttgttc agcataatct ttgaattgtt 5640 cctcgtataa ctaatcacaa cagagtacgt gttcttcttc ctgttataat ctaaaaatct 5700 catccagatt agtcatcctt tcttcttaaa aggaaccttt aattatcaat gtatttattt 5760 aatatttaaa ttagcttgtc aaagtctagc atatacatat tttgattata ttctgagaaa 5820 tgcacctgag ggtgttcctc atgatctact tcaacctctg ttattattag attttctatc 5880 atgattactg gtttgagtct ctaagtagac catcttgatg ttcaaaatat ttcagctacg 5940 tacttgatgg ggtgccccga atgagagaga ggccaattgg ggatttggtt gctggtctta 6000 agcaacttgg tgcagatgtt gattgctttc ttggcacaaa ctgtccacct gttcgtgtaa 6060 atgggaaggg aggacttcct ggcggaaagg tatggtttgg atttcattta gaataaggtg 6120 gagtaacttt cctggatcaa aattctaatt taagaagcct ccctgttttc ctctctttag 6180 aataagacta agggtaggtt taggagttgg gttttggaga gaaatggaag ggagagcaat 6240 ttttttcttc ttctaataaa tattctttaa tttgatacat tttttaagta aaagaatata 6300 aagatagatt agcataactt aatgttttaa tcttttattt atttttataa atattatata 6360 cctgtctatt taaaaatcaa atatttgtcc tccattccct ttcccttcaa aacctcagtt 6420 ccaaatatac cgtagttgaa ttatattttg gaaggcctat tggttggaga cttttccttt 6480 tcagagatta tccctcacct ttattatagc ctttctattt ttaaacttca tatagacgcc 6540 attcttgttt taaaaaacac taagttttct tttagttata ccttcccctc cttattctct 6600 ccaaagtaaa tattgtagca agtgttggtt gatccattgt gaatcttatt atcctattta 6660 acatgcaggt gaaactgtct ggatcagtta gcagtcaata cttgactgct ttgcttatgg 6720 cagctccttt agctcttggt gatgtggaaa ttgagattgt tgataaactg atttctgttc 6780 catatgttga aatgactctg aagttgatgg agcgttttgg agtttctgtg gaacacagtg 6840 gtaattggga taggttcttg gtccatggag gtcaaaagta caagtaggtt tctatgtttt 6900 agtgttacat cacttttagt atccaaaatg caatgaaatt aaaactcatg tttcctatta 6960 ggtctcctgg caatgctttt gttgaaggtg atgcttcaag tgccagttat ttactagctg 7020 gtgcagcaat tactggtggg actatcactg ttaatggctg tggcacaagc agtttacagg 7080 tattcatgaa tgacactatc ttctattatc ttttatttta tagcttacac tatcattcct 7140 aattcaaccc ccttcttttc tctttcccct cactcccaaa atagagctta tcattgtatc 7200 cttaatagct cttttatgtg ctgtttcatc tcttgagcag attctacatg attatccttt 7260 ttagtgaact tttttgtctt ttaaataatt gatatcatca tttgaacttg cacatcatct 7320 ctatccttcc tcattttatt atatttcatt aagagtgata aaattacatt gtcaagtaaa 7380 gcaagttagc gtatcagata atgatgcttc gattgcagaa ttggtgaaag cttgcacaat 7440 tcattagctt agtgacaatt gtgatgtaga tagccataat cttccatgca acttattatg 7500 ctttttgtct aaaacttctt ttgcacttaa acatgaatta gagagttagg atgaacaata 7560 gtaacagaca caaagcttat ttctagacca cccagtggtg aagacgaagc agcatgagtg 7620 agattaatgg cagcatctga ttgaagcttc ttttggtatt attggagatg aaatcttgag 7680 ccaaattagg gcttttgcct cctcaatagc cattggttca aaattgcttt caataaaatg 7740 attacagaat caaattctta agaaagacct tcaagaacaa catcaagatg tttcctgtgc 7800 aaaacaggct cacctacaaa agagtgtcta caagcacctt tacacttgca aaaaattcct 7860 taactgaaca attgccaaga gtcatgttgc aaacttgaga ttggagttga ttagatttgg 7920 tgtgtgtgag attctggaaa tgagcatgaa gttttttgca aagctcataa aatgaatgca 7980 gccaagaatc ctagatagga ttgaatttga gagagaggct tgaagtcaag ataaccgcaa 8040 ctgatcttgc tgttcccatg ctgcatagga ctcgttgatt ctaccaagat aacaatcttc 8100 tgtggtgaga atatgagtgg gaattgtcag gcaacaaaga aaatgaaggc tatgagcctt 8160 tgttaaggtg cagagagaaa acagaaaatg aagaacttgt gtattgaagg aattgaaaag 8220 ccaattacaa ttgtgttgca gagagatatt tatagttctg aagtgtataa ctaactaaac 8280 agaatgctac caacctagag gcagttgaga attgctccct tattacaata ctctcacagc 8340 cttgatgata ggcttgattt gctgccaccg aagaagaaca ttattgttgg agagtttttc 8400 agtgattgca tcagagaaag ttacaagtgt gattggagat gaaggacttg cggtcgtcga 8460 aggttaagtg ttaagtggtg gaatgtgtat cggaggtggt tgcctagccc aagaagctgg 8520 ttgcagtgga agcggatgcg gcagaagcca tgggttcaga tcagaactat gttctagata 8580 ccatattagg gttagctttc aagagaaaac ttatgaaact gaactgtaaa ctgttgtatt 8640 attgattagc tgatctagta gtgatggaag cttgcttgcg aagcttctat ggaggctgga 8700 tcattgagct tcaatgaggt ccttcaatgg tgatttttca ccatggagat gcagcggaag 8760 ataaatgaag aggtgagagg aggcgtcatc cactaggaaa taaactatgg aagaaggagc 8820 ttcaccacca agagagtgtc ttggataaga agcttagaga ggaagcttca atggaggaat 8880 agaaagagag agggggaaca aaaaattgaa ggaggaaaag agggagagaa gttgaacttt 8940 gaagtgtgtc tcacaagact cattcattaa agttacaaca agtgttacac atgcttctat 9000 ttatagtcta ggtaacttcc ttgagaagct agaacttaac tacacacacc tctctaataa 9060 ctaagataac ctccttgaga aatttccttg agaagcttcc ttaagaagat tcctagagaa 9120 gctaaagctt agttacacac acctctctaa taactaagtt cacctccttg agatgagaag 9180 ctagagcctt agctacacac acccttataa tagctaaact cactctattc caaaatacat 9240 gaaaatacaa aaaagttcct actacaaaga ttactcaaaa tgtcctgaaa tacaagacta 9300 aaactctata ctactagaat ggtcaaaata caaggtccaa aagaaggaaa aacctattct 9360 aatatttaca aagagagtgg acccaacctt agtccatggg ctcagaaatc taccctgagg 9420 ttcatgggaa tcctagggtc ttctttagta gctctagtcc aattttcttg gagtcttcta 9480 tccaatatcc ttgggggtag gattgcatca tgtagtacaa gagaggggaa tatatataca 9540 gttgtaagtt gtaactacct aatcaaaccc aactgactca ccatacacag aaaaacaatg 9600 tacaaaggat aatagaaaaa ctgaaactga gatatactca ttacatagaa gaattacatg 9660 atgaatctga aaattttaat tgggaaactg aggacaataa caaggctttc agagttcatt 9720 ttgacaatag gtaaattatg gacttcaact tagacctcaa gggtatgctt gggagtgggg 9780 ttttagagga aaaggggaag gagggaaatt ttttaattct agtaaatatt ctctattttg 9840 attaattttt aaaataaaac aaataaactt atagattagc attcacttaa tgtcctgatc 9900 ttttatttgt ttcatgaagt tttttatagc ctttctgttt ctgttaaaag aaattggagg 9960 gtgttcataa tctatatgcc catatatatg tattgtcctg ttgtctgtgt ttctgttttc 10020 tttctttagt gtctcgcctt tccttaattc cttatcaaca ccttgtttat ttttgaaaac 10080 ttaaatgtcc tcattttttt tacctgtact ataactttcc aaacaaatag tagaaaatgt 10140 ttcaaatatt ccccagaact gtttcagtga acaaagttca agccagaaaa aaagcaagca 10200 gaggctaaag aagtatatct tattgtgaag agtaatctca attggttaat tatcgaattg 10260 tatcatttta caatagaaaa ttagaagtgg gttgattagt ttatacgaac aattatttaa 10320 atagggttga tggtgtggtt aattactgat catatgttaa gactatgagt cgatgaccag 10380 cctcagtgca gtcattttaa gttccattat tttttaattg tgcttatgtt taactttgtc 10440 cttcttttaa agggagatgt aaaatttgct gaagttcttg aaaagatggg agctaaggtt 10500 acatggtcag agaacagtgt cactgtttct ggaccaccac gagatttttc tggtcgaaaa 10560 gtcttgcgag gcattgatgt caatatgaac aagatgccag atgttgccat gacacttgct 10620 gttgttgcac tatttgctaa tggtcccact gctataagag atggtatggt ttagctgttt 10680 gtttttgctc aagagcttgt tttcacatat ttgtggtcaa gagcggttta gctgtttttt 10740 tttttaaatt gtggttaatg aaattattat aattatacta atattgaaat tggatcacta 10800 accatgtgaa atgcttgaat ttttagcttg aaaacttctt ttgtggatga tttttctttt 10860 atctatgtag tgtggggcat ctatgttgtt cctttaagct ttgtgtcata gttgtacaac 10920 ctggtctgtg ggctggtcca gttcttactc atgactgtct tttgcagcaa actggttaaa 10980 cttgggtgac ctgttgaccc acccagattg gcctgttctt ttttaaataa aactccaaaa 11040 ggctacttat aagatttcaa catgatactt gaatgaccac ccttacttta aaggtcatta 11100 tgccatcaga ccccttgatt ctctgttcag ttatgttctt attcttatta ttttttaatt 11160 tatattatta tccaacgatc tgatctttgt acatgatgct ggacaatcat caaagctagt 11220 ttggttacat catataatac cttttttttc ataaattatt ttttcccata atatatttat 11280 atgtattttt ttaatacaat attctgggga aatttttttt ttctgttttc ttttttctgg 11340 tttgaatact atttcaatga ctgggcctta ttattttctg gtttgggtta tacaactgtc 11400 ctttgatgta cttttgaatg cttcaatagt atttttcata atcatggaag gcactagagt 11460 gcagtgcata ttgcacaagg ttctttaatg gcatcttgaa tttgttagaa catggagtta 11520 tgatatacaa ccattcctat gtcttcatct aatagctaaa gcttttggcg tagttggtta 11580 acatggtatt ggaatcttat tttaaaggtc catcttattc gcaagtacaa ggcaggtgga 11640 cctgcgcatt attcacgtgc caggctcaaa gggattttgt atgaggggga atttttggaa 11700 tataatatat agaatcattc atgtggttca cctatcatgt gtcaactcaa gtttttgtcc 11760 tagttgtatt attgcagtgt ctaaactagg catgatcttc tgtggaagga aatttaacct 11820 aaggaacttg aatgcttctt gttctgagat ctttattttt tttctccaat ctttttaata 11880 cttgaaaggt tttagttgta tctataaagg gtgcagaatt agggggtcag cttttctgtt 11940 gtaagcgtga attaagtgca ttttatgttg ttccctattt tatacatttg aactatcaac 12000 catatcattt agcaaacttc tttgttgctc agattcccat ttattcttgt ttcctctatt 12060 ttttagtggc aagttggaga gttaaagaga ctgagaggat gatagcaatc tgcacagaac 12120 tcagaaaggt cttgctaatt cctttatggt ttctatatta ctggactttt tacatctcac 12180 tgacctacta ctgtcttggt atttcagcta ggagcaacag ttgaagaagg tcctgattac 12240 tgtgtgatta ctccacctga gaaattgaat gtcacagcta tagacacata tgatgaccac 12300 agaatggcca tggcattctc tcttgctgct tgtggggatg ttccagtaac catcaaggat 12360 cctggttgca ccaggaagac atttcctgac tactttgaag tccttgagag gttaacaaag 12420 cactaagcat tttgtacatt gagtagggaa gagagagaga tatatataaa tactcacaaa 12480 gcagtgagta tatggcttgc ttttgtttct aaacattcct ttataaggac ttgagataat 12540 ttgtattgtt taaaagagcc attggttctg ttgtatcaaa gtaatttaat tttcagtacc 12600 gacttggctc tactcatatg tggtggtgta cattgcatct ttgcatttga ttccatatct 12660 attgggatgg gaccatacat tttttgttta ttatttaagt caaacatatc agataatatg 12720 tggtgaccag aaaagtgtct agcaatcaaa tgggtctgtg attgcatgtt tgagttcagg 12780 acatttatta atgagtgaca gaattttaaa aagctcgcca ataggagttg ccacatctga 12840 tcgagtcttc tgtaaacact aactgtaact tgagtttgat aatcagattc cccccgttgg 12900 taggtaatat gtaaatttca ctatagattc ttactgagga tgatggtctt gacttcgaag 12960 tggtgagtgt aattctctaa tctaaacttt atatatatat aaaaaaagaa tgttaaaaac 13020 ttgagtgaca tacagcaaat agcaatgaaa gcatgaccat ggccttgggg ggccaaatgg 13080 ccatgtacca cttttccacc tacttgagag ccatggtcct gaatgaggtc cttttgtttc 13140 atttttttta caataaagaa agttcatatt cttggcaata gcaaggcaaa tcatttgtgg 13200 aagtcacatg aaattcacca taggcttcat tgttcaaatc ctttagtcac taaggcaggg 13260 cctatgtaag aattttgact actcttgtaa atgctgtgcg gtaaagacta cgggaaaata 13320 taaattattg catatctaga ggtgaggttc atttctccga tccatttctc caagtaataa 13380 aaatatatat aaattattaa tatggtatga tatggttatt tgtcctttaa atatgcgatt 13440 ataggttcaa tctttggtta atctatcaaa tgcatctcaa tattttgaga gaatagtttt 13500 tagctcttga ctgagagata ctttgagtta aaaaaatgta tttataaact attgtctatt 13560 gaatttttat tttttttgta acaccacatg tgagtatttt actaaatcca tgttacaatg 13620 tactgaatgt tttacaatac agtctggttt gataataaaa tatgcacaaa gtccagctta 13680 tgtaactctt tcaattcatg gaaaatgatg atatgcgaat tgaaagaaag aaaaccataa 13740 tgtaagtgta tttttttttt ctttctcttc tttaatatta ctcaatatca gattgcacat 13800 gggaagggta ctggctcatg tgggatatta atttttatcc cttacctaaa aagagagaaa 13860 gagaaaataa ctatttaaaa agagtaccac caccaccttt ttcgctttta agttttgttc 13920 tgttttcact actctttcat gcgttgtttg ttggcttccg atagtgacga atatgataat 13980 gattttacgt tgagaaaaaa aatgtgccat gtaaattcca gagattgaaa ttttagcttc 14040 aaattaatat ttattttatt atcttttcaa attggttgca tgtgaaagaa tttgaagttc 14100 ttcaacaagg aaataaacac ttcaatgctc aatccttaga gtcagtcact agatcccaaa 14160 agaatgtgat gtttacacac attagtatat atatatatat aaacacagct tatattatat 14220 taatgagtga tgcgcgagga cggtggtgac actacatggc caaaacaaga aatgtaattt 14280 aatttttttt tctttaagta ttactctatc cttgaatatt agtcttaaat cttcaaagac 14340 cttgcgaacg aagcaatctt gtcctgatcc tgtgattgtt ctacactagt ccttacgtgt 14400 acctaagcac atgatacttt gctgccctaa cataaattgt accataagga ttcttgggga 14460 gatgcttttg ccttcatttt caagtttgtt tacactttca agtcgttttt tcaatgcatt 14520 ctctttcctt tctgggaccc cttgtcttta acacgcgcgc acacaaaaac tagtagacaa 14580 taattagtac tacttgggtt ccattaaatt gtaactacat atacatgtgt tttttttttc 14640 ttggatcaac tgcatataca tatgttttat gagtttcatt gaatttatat ttacacaaac 14700 agttattaaa acataatgta gagccttgtc attaacctga tgttaggatt ataatttcat 14760 gctttgattt tgattgtacg ttttttgttt ttattgtaaa gtgtttattt tattaaaatt 14820 tgtcttggag tgctgtgatc tttagggtgc accgttcaaa agagagacga caaggataat 14880 actaatacta gtagattcca cgcattcaac cctagttagt ttagctatga caaattaagc 14940 atggtaagaa aaggggagga gaaaagtaag aatgaaaaca tataacaaat tgtgattgaa 15000 cttttccatg acgtaatgaa aacattaatt ttaagataag cttcaactcc taagaagaga 15060 tatgtcaaag aaacttagga ttttttctct atttataacg gtaaattact catcctttta 15120 aatgattaat ttgcgttgtt gaattcgttg taaagggaaa atcaagaagt ctcttcacgg 15180 gaaagttata tcaaagtatc atatactaga cttcatggct agcttttact ttgattataa 15240 gtaatgcatg caattaatgg gcaaataaat tatttgaaac caactaaagt acaaataatt 15300 ttcctccaaa acctctcaag ttcgcattga aattaaataa accaatgcat attaaggcgt 15360 aaatctaaac catgtttgtt tcatcttgta ttgtatatca tagtattaat aaggtacttt 15420 gaatttagtt gttattgacc gttaaattta ggggtgagtt gttttactat ctcttactca 15480 attgctttta ttcaacgcaa attctagtag gattttcagc ccaaattaaa agaagtttta 15540 cggtttgatt ctctacaaac ttgaattgag atttctaatt tcagaaatca ataattgcgg 15600 tcttaattaa ctctataatc aaacctttta acccaatctt tttctcaatt ctctgaatta 15660 agacaatcaa aatttaaact cacacgaatc tcacacgcct tcccacggta gagaaatata 15720 gggagtccct taatagcaaa agcctcaaaa ttcagaaaat ctcatccatt gcatttgcac 15780 attcaacaaa ccacccatta ttatgttccc ttaataaatc tcacacttaa aaaccctcct 15840 cacccataat taacccaaaa ggaagtttcc tccacacaaa aaatatcctt aaacaaagag 15900 cctctataaa tctattttaa aaaaaccccc aaatttaagg a 15941 36 15172 DNA Glycine max EPSPS with double mutation 36 aaaagtctga atgaagtgaa gttgttgtgt tagggggatg ctgaatttga ttttaattta 60 atttaaataa attacctgtg taaaggattt ttgtaccgcc ttttaatcac aaattgtcgt 120 gtatcgaaag tttgttgaat tttatagtaa ctatcttgga ggttatacct agtaggattt 180 ctgattagtt aaccatgtaa atttttttaa tgggtttgtg tttgttttaa ctgatgttgt 240 ttttgatatg tacgtggtaa gtgtgatgag tttgtgcata tcttgatcaa agactgaagt 300 gaagttgttg tgtttggggg gttgactctt ttaggaagag gatttgaggg aatttcgcca 360 atgggggagc agaactccgg gacaccctga gaattttgag actccgggaa ttgaagttac 420 aacaggtttg atatgagtta gagtttgtat aatagaatag taattctttt tattttttat 480 ttttattgtt tatttatcca ttattgctat ttttgtaggt cctcttggtc aggggattgc 540 caatgctgtt ggtttggccc ttgcagagaa gcacttggct gcaagataca acaagcctga 600 caatgagatt gttgaccatt acacgtaaaa ataactaaat catacacaac ttgcaagact 660 ttagttgttg gtgttttgct aatggcgttt gttttatgca ggtatgctat tctgggtgat 720 ggttgtcaaa tggagggaat tgcaaatgaa gcatgctcac ttgctggcca ctggggactg 780 gggaagctga tagcatttta tgatgacaat catatttcta ttgatggtaa cacagagatt 840 gcgttcaccg agagtgttga tagtcgtttt gagggacttg ggtggcatgt tatttgggta 900 aagaatggaa ataatggcta tgatgatatt cgtgctgcca ttaaggaagc aaaagctgtc 960 aaagacaaac ccacattaat caaggttagt ttactaattg tggcaatgat atgcatagat 1020 ttctggcttg tagttaccat aacaatcata atctgtcatg atttataggg attcttttaa 1080 actaaggtta taaacatgat atgttactaa agactgcatt gcattgtagt acctcatttg 1140 agaaactgga agttataggt gggaaatcaa aatagtaaat tatgggtcag tttattaagt 1200 gtagctggtt tgtcttttgc taactctatc atttcacagg tcacaacaac cattggttat 1260 ggttctccta acaaggctaa ctcctacagt gtgcatggaa gtgcactggg tgccaaagaa 1320 gttgatgcca ccaggcagaa ccttggatgg tcacatgagc cattccacgt gcctgaggat 1380 gtcaaaaagt atggatgatg ggtttagaga tttctttttt cctgtgacac tgctgatgtt 1440 tataatgata ctgaataaga attgcttgtc tgtccccagg cattggagtc gccacacccc 1500 tgagggtgct gcacttgaag ctgagtggaa tgctaagttt gctgagtatg aaaagaaata 1560 caaggaggaa gctgcagaat tgaaatctat tatcaatggt gaattccctg ctggttggga 1620 gaaagcactt ccggtgagta aattctaaac tcacaggttt ttcttacatg tttgtaactt 1680 ttcaaggttt ggattacata ctatccaaag ttgatcatga tttcagtttg atttggtagt 1740 atggggcttc aaaaagttat tccaaatatt aaaacctggc ttccaatttg atttcagaca 1800 tacactccag agagcccagc ggatgccacc agaaacctgt ctcaaacaaa ccttaatgcc 1860 cttgcaaagg ttcttcccgg tctgcttggt ggcagtgcag atcttgcttc ttccaacatg 1920 accttgctca aaatgttcgg ggacttccaa aaggatactc cagcagagcg taatgttaga 1980 ttcggtgtta gagaacacgg aatgggagct atctgcaacg gcattgctct tcacagccct 2040 ggactgattc catattgtgc aaccttcttt gtattcactg actacatgag aggtgccata 2100 aggctttctg cgctgtctga ggctggggtt atttatgtca tgacccatga ttcaatagga 2160 cttggagaag atgggccaac ccaccagcct attgagcacc tagcaagctt ccgggcaatg 2220 ccaaacattt tgatgcttcg tcctgccgac ggtaacsgaa acagccsgag catacaaagt 2280 ggccgtgctc aacaggaaag agaccctcca ttcttgccct atccaggcaa aaactgcccc 2340 agcttcccgg aactthcatt gaaggagttg aaaagggtgg ttacaccatt tcgggacaac 2400 tccactggca acaagcctga tgtcattttg atcggaactg gttcggaatt ggaaatcgct 2460 gccaaagctg ctgatgacct aaggaaggaa gggaaggctg ttagagttgt ttcccttgtt 2520 tcttggggaa ctttttgatg agcaatcaga agcstacaag gagagtgttt tccctgctgc 2580 tgtttcagcc agagttagca ttgaggcagg atcaacattt gggtgggaga aaattgttgg 2640 agcaaaggga aaagcaatag gcattgatcg ttttggagct agtgctccag ctggaagaat 2700 atacaaagaa tttggtatca ctaaggaagc tgttgttgct gcagctaaag agcttatcta 2760 gaacttttga tttttttttg ccttctggtt ttggttgaga gcattccatg tcatgaataa 2820 gaaaaaggtt aaatatcctt cgattgggaa tttgggattc taagtgaaga agcaacatag 2880 atcaaagaat tttgtgaact tgtaataact atttgacaat ttagttttgc actgccacat 2940 ggttaaattc aatgtttgat catatcaacc atagatgcta gtttatacta cttgtataat 3000 ttgtttcact tgcagattca ctcttagcat ttgagtgttt ggatggccgt gttttgttca 3060 ttaagaaatg ttgacatgga tagtttgttg catggtaaat tggtgattaa taccttttta 3120 agcttctttt ggcaagttgt taaaaagtgt tttgttttaa tctctagtta atctaaaaat 3180 gcctacttat tttattttga ctttcaaaac ttgtctatat gccgagtata aaaaaaactt 3240 gtctatataa gttccttatg gaaaaaggac ctacaaaata atttaaaaat gctgaatttg 3300 ttaggaagtt tgacaacttt agacattaat aattgttttt ttttcatata tataattgac 3360 tttcaaaact tgtctatata ttataaattc gttatggaaa gggcgaccac acgtaaaacg 3420 taacatgcca atctctccct agtgaactgt tattctcatt cagtttttgt aagttcacct 3480 tcaaattttc aatttttttt ttgacaaaaa tatctttgat ggaacacgtt aggggtgtaa 3540 attcaccatt catcatttca ttcattatac acaatagtct ttcataatcc aatgaaaact 3600 tgtttttgtt gttatttttt tctgaaaaat ctttataaaa taaataaaaa catttttttg 3660 ttataaattt cagttgaaat acataaccat taattctaca gagtgttaat gttgatgtaa 3720 aataaaaaaa tattggatat caaacttaat gaacagaaca aaaattacaa aattgtacaa 3780 tttaaatgat aaaaaaccaa attcacaaaa ataaaaatta aggacgaaat ttgagaaatg 3840 ataattaaaa acgattaaaa atataattaa actaaaattt attatgtaat tctttaatat 3900 atatatatat atatatatat atatatatat atatatatat ataataaaag ttttacatta 3960 taattttgaa atgaagtatt tgataaacga acaacccacc cttggggttg gtgagagtga 4020 aacggagaac agtgtctccc tcacttggtc ttctgagtcg agtcctattc atcaccaacc 4080 cactcgtcaa aattgttgta tgctatgtaa ccattttgtt ttttaataaa taaaagtgtt 4140 ttgttctgct atgcactccc catcaaatac catttacttt ttttttgtct tctatcaatt 4200 tctatttagt tcctagttgc tacaacttcc agctggtgaa aaatagtcaa cagagactac 4260 aatattctaa taaaatagaa taacaaaatc aaatatattc atttaatatg attttatttt 4320 tatttaattt aaaacatgaa ttatttgttt cttatttaat taccgtttcg ttcacttctc 4380 aattaataaa ataaaaaatt tctacaatta tagaaaaagt ttagttttgt agattgttaa 4440 cataaagatt tttcctatta actaattaat taaaagtcat cttatatata agttttaaag 4500 taattatctt atatatgtac ccaaaagttt taaagcaatt attataaaaa agtaaaattt 4560 tatcatatac aataatctat aattacatga aagtataatt tttaaattat taatacgtta 4620 aaattatttt tttaaaattt gaatgatcat atagtaattt tattttatac caagtcccaa 4680 catttcctat tttattccac ttttaccaat aaatttcctc ataaacactt ataagaaaaa 4740 aagtaagtaa agaataaaat aagcttttct ataaactata aacaaatttg tataaacttt 4800 cttatattag tttttctgaa aactaatttt aaattataca taaattgaat ttactgataa 4860 ttttttattt tctttttgta taagtgtttt ttaagaaatt tgttcaaaca tatttttatg 4920 acatgtcaat gcttgagaga tataaggtga gttaaatcat aaatgattaa agaaaaataa 4980 aagaagaaaa agataattaa tttaattttt tattaacatt ctaacaaatt aacattatat 5040 aaataaaaat aatatttcaa taattggatc aataatacta ttgttcttaa acaccaaacc 5100 aaccttccta aagtcctaat ctaatccaaa agccatcatt cattttcctt ggtaggtaaa 5160 gttccaaaac ctttaccaac cttttcactc aattattttg gtgtaagcaa ttcgacatgt 5220 gttagtgtta gttggcaacc aaaaacccct ttatgtgact cactcaatcc aacaacctct 5280 cacaccacca acccccccat aactcataag gccaaaacca tttctcacaa aacccttcat 5340 tacacacatt attatcatta tcacacacac aaaaaacctc tcatttcaaa gagagagaga 5400 gatttcacag accaaattgc agaggacgac aaagttcaca acttcaagga aaatcgaaat 5460 ggcccaagtg agcagagtgc acaatcttgc tcaaagcact caaattttyg gycattcttc 5520 caayyccaac aaacycaaat cggygaattc ggtttcattg aggccacgcc tttggggksc 5580 ctcaaaatct cgcatcyygr tgmayaaaam tggaagcytt atgggaaatt ttaatgyggg 5640 gaagggaaat tccggcrtgt ttaaggtttc tgcatcsgtc gccgccgccg cagagaagcc 5700 gtcaacgtcg ccggagatcg tgttggaacc catcaaagac ttctcgggta ccatcacatt 5760 gccagggtcy aagtctctgt ccaatcgaat tttgcttctt gctgctctct ctgaggtaaa 5820 gtttatttat ttatttattt ctgtatccaa aaatgtaaat tgttagtttg ttaatttttg 5880 ttagcagtga gagtcgaact acttggcttc tttcttagtc atccaaccaa ccttatatct 5940 ccaaaattta tttattggtt ttttttgggg ttatgtggtt aggaatagga gtttgatgcg 6000 tggagtggat tttgaatatt tgattttttt tttttttgta ttattcagtg aaaatgaagc 6060 atcttgtccc atgaaagaaa tggacacgaa attaagtggc gtatgattta gaatgatgat 6120 agaaatgtgt ataggtggtt ttaatgtgta gcaataagca tattcaatat ctggattgat 6180 ttggacgttt ctgtataaag gagtatgcta gcaatgtgtt aataatgtct tgttaaaagt 6240 atggatggct aaaataatca taaaaatcga gtgggagtag tatacatatc tacaggaaat 6300 gtattaggtg aggcatttgg cttctctatt gcgagtaagg aacaagtaat ctcagttaat 6360 gtgaaaatca atggttgata ttccaataca ttcatgatgt gttatttacg ggaacgcaat 6420 attgactgtt gattttatct gcagctgaga ttatatacta tatccttcca aagaaatctt 6480 tgactcttga ttatccaagt atggttgtat taccaatttt agctctagaa gataatccct 6540 cccccaaaac acaaattaga atggtgctgc aagttccgtg ttactttcat tctattattt 6600 ttataacttt taattattta atagatgtct tgtttggcat aaactataat ttattctgtt 6660 tttttttatt cttatttagg gaacaactgt tgtagacaac ttgytgtaya gygaggatat 6720 tcattacatg cttggtgcat taaggaccct tggactgcgt gtggaagayg acmaaacaac 6780 caaacaagca attgtkgaag gctgtggggg attgtttccc actaktaarg aatctaaaga 6840 tgaaatcaat ttattccttg gaaatgctgg tactgcratg cgtcctttga cagcagctgt 6900 rgttgctgca ggtggaaatg caaggtctgt tttttgtttt gtttgttcat catgatctct 6960 gaattgttcc tcgtataact aatcacatca gactatgtgt tcttcctcca tcctgttata 7020 atctaaaaat ctcatccaga ttagtcatcc ttctttaaat gaacctttaa ttatatctat 7080 gtatttattt aacatgtaaa ttagcttgtc aagtcaaagt ctagcatata gatatactga 7140 ttacactctg aggaatgcac ctgagggtct taatcatgat ctatttcaac cttgccactt 7200 tcttctttta ttattagatc acctatcatg attactggtt tgagtctcta aatagaccat 7260 cttgatgttc aaaatatttc agctacgtac ttgatggrgt gccccgaatg agagagaggc 7320 caattgggga tttggttgct ggtcttaagc arctyggtgc agatgttgat tgctttcttg 7380 gcacaaactg tccacctgtt cgtgtaaatg ggaagggagg acttcctggc ggaaaggtat 7440 ggtttggatt tccattagaa taaggtggac taactttcct ggagcaaaat tctaatttat 7500 accctgtttc cccctcttta gaataagaca ctaagggtat gtttaggagt tgggttttgg 7560 cgagaaaggg aagggagggc aatttttttt ctaataaata ttctttaatt tgataaattt 7620 tttaaacgaa ggaatatgaa gatagattag cataacttaa tgttttaatc ttttatttat 7680 ttttataaat attatatacc tctatttaaa aacaagatat ttttcctcca ttccctttcc 7740 ctttaaaacc tcagttccaa atataccgta cttgaattat attttggaag gtgtattggt 7800 tggagacctt tccttttcag aggttatccc tcacctttat tatagccttt ctactctctt 7860 aatgagttca ttgtgcattg agtcattgaa cttcctgtga aaagaaattg tttacttttc 7920 tttatttgtt acctacatcc ttattcctgt tttaaaaaat actaagtttt cttttagtta 7980 tgccttcccc tccttattct ctccaaagaa aatataatag cgaatgttgg tttatccatt 8040 gtgaatctta ttatcctatt tcacatgcag gtgaaactgt ctggatcagt tagcagtcaa 8100 tacytractg ctttgcttat ggcagctcct ttagctcttg gygatgtgga aattgagatt 8160 gttgataaac tgatttctgt tccatatgtt gaaatgactc tgaagttgat ggagcgtttt 8220 ggagtttctg tggaacacag tggtaattgg gatargttct tggtccatgg aggtcaaaag 8280 tacaagtagg tttctatgtt ttagcattac atcacttttt agtatccaaa atgcaatgaa 8340 atcaaaactc atgttttcta tcaggtctcc tggcaatgct tttgttgaag gtgatgcttc 8400 aagtgccagt tayttmctag ctggtgcagc arttactggt gggactatca ctgttaatgg 8460 ctgtggcaca agcagtttac aggtattcat gcttgacact attttctatt atcttttatt 8520 ttatggtcta tactgtatca ttcctaattc aacccccttc ttttctcttt cccctcactt 8580 ccaaaaaaat agagcttatc attgtattct taatagctct tgtatgtcct ttttcgtctc 8640 ttgagcagat tctaccgtga ttatcctttt tagtaaactt tttttttgtg tgtcttttaa 8700 ataattgata tcatcatatg aattcacaca tcatctctat cccttcctca ttttattata 8760 tttcattaac agtgataaag ataaaaataa attgtcaagt aaagcaagtt agcatgtcag 8820 ataatgatgc ttcaattgca aaattggtga aagcttgcac agtacattag ctttggtgac 8880 aattgtgatg tagatagcca taacctccca tgcaacttat tatgttgttt gcttaaactt 8940 cttttgcact taaacacgga ttagagagag tgaggatgaa caataataac agacacaaag 9000 cttagtttta taccacccgg cacccagtgg tgaagaccaa gcagtatgag tgagatcaat 9060 ggcagcatct gattgaagct tcttgtggta tttttggaga tgaaatccga ggcgaattag 9120 ggcatctggc tcaacaatag ccattggttc aaacttgctt ttaataaaat tgattacaga 9180 atcaaattct tgaggaagcc ttcaagaact acatcatgat gttccctgtg caaaacaggt 9240 tcaccgacaa aagagaacat ctacaagttc ctttacacat gccaaaaatt cctcaactga 9300 acaattgcca agagtcatgt tgcgaacttc aggttggagt tgacgaaatt tggtgcatgt 9360 atgattctgg aaatgagcat gaagtttttt cctaagctca taaaagtgaa tgcagccaag 9420 aaccctagat aggattgaat cggagagagg cttgaagcca agataacagc aactgatctt 9480 gctgttccca tgctgcgtag gactcattga ttctaccaag atcacaatct tctgtggtga 9540 gaaaatgagg gtgaattgtc aaccaataaa gaaaatggtg aaggctgagt cttgatgata 9600 ggcttgattt gcttgcgctg aagaagaacg ttattgttgt agagtttctc agtgattgta 9660 tgagagtaag ttacaggtgc gattggagat gacggacttg tggtgggagg agggtaagtg 9720 ttaagtggtg gaatgcgtat cagaggtggt tgcccagcca aagaagctgg ttgcggtgga 9780 ggaggtggtg gtgcagtgga agccatgggt tttgatgctt ttgagagaaa acatacgaaa 9840 ctgaactgta aacttttgta ttattgatta gctgatttgg tagtacaaga gaggaatata 9900 tatacagttt taatgtaact acctaaccaa acatgaggaa ctctccatac acagaaagac 9960 gtatacaaag gataacagac aaacagaaac ttagatatac tcatacagag aagaattaca 10020 ggatgaatct gagaatttta attgggaaac tgaggaaaat agcaagggtt tcagaattca 10080 ttttgacgat aggcaaatca tggacttaac ttagacctca agggtacgct tgggagtggg 10140 ggtttttaga gggaaaaggg aaggagggca aacttttaat tcctaataaa tattctcttt 10200 tttgattttt ttttaaataa aacaaataaa cttatagatt agcatacact taatgtccta 10260 atcttttatt tatttgcatg agtttttttc ttttatattc tttctgtttc tgttttcttt 10320 cttcagtgtc tcttgtcttt ccttaattcc ttatcaatac cttgtttatt tttgaaaact 10380 taattttcct cattttttta acttataggc tatactatag tatgtataac tattcaaata 10440 aatagtagaa aatgtttcaa atattcccca gaactgtttc agtgaacaaa gttcaagcca 10500 gaaaaaagaa gtatatcttc ttgtgaagag tagtctcaag tggttaattg tcaaattgta 10560 tcattttaga atacaaaatt agaagtggtt tgattagttt atacgaacga ttatttaaat 10620 agggttgatg atgtggttaa ttactgatca tatgtgaaga ctgtgagtcg atgaccagcc 10680 cagtgcagtc attttaaatt ccattatttt ttaatttgtg cttatgttaa actttgtcct 10740 tctttcaaag ggagatgtaa aatttgctga agttcttgaa aagatgggag ctaaggttac 10800 atggtcagag aacagtgtca cygttwctgg accrccacra gattyttctg gtcraaaagt 10860 cttgcraggc attgatgtca atatgaacaa gatgccagat gttgccatga cwcttgcygt 10920 tgtygcacta tttgctaatg gtcmmactrc yatmagagat ggtatggttt agctgtttgt 10980 ttgtgttcaa gagcttgttt taacaaattg ttttttttaa ttatggttaa tgaaattatt 11040 ataattacac taatattgaa attggatcac taaccatgtg aaatgcttga atttttagct 11100 tgaaaacttc ttttgtggac aatttttctt ttatctatgg attgtggggc atctatgttg 11160 ttcctttaag cttcgtacaa cctggtctgt gggctggtcc agtccttctt actcatgaca 11220 gtcttttgca gtaaactggt taaacttggg tgacctgttg acccacccag attggcctgt 11280 tctttttaaa taaaacttgg ctacttataa gatttcaaca tgatacttga atgatcaccc 11340 ttactctaaa ggccattatc tgttcagtta tgttcttctt cttcttatta tttttaattt 11400 atattattat ccaacgatct gatctttgaa catgatgctg gacaatcatc aaagctagtt 11460 tggttacatc atataatacc ttttttttca tatattattt ttcccatagt atatttttgt 11520 gttttttttt catacaatat tattctgaaa aaaacttgtt tcgttttttt cctggcttga 11580 atgctatttc aatgactggg ccttattatt ttctggttta ggttatacaa ctgtcctcca 11640 attgactttt gaatgcttca atagttttct tcttaatcat ggaaggcact agagtgcata 11700 ttgaatatgt tagaacatgg aaggcttaaa tatcttttta gtctttgcaa tttaacgttt 11760 ttttgctttt agtccttgca aaattataat ttttttttag tcctgactaa ttatgtttgt 11820 tttgtttttg agggcgagcc ctggtgcagc ggtaaagttg tgccttggtg acttgttggt 11880 catgggttcg aatccggaaa cagcctcttt gcatatgcaa gggtaaggct gcgtacaata 11940 tccctccccc ataccttcgc atagcgaaga gcctctgggc aatggggtag aaaaagaaga 12000 atgctttaga taacactttt tttgttactg ttcaaagcac tatctaaagt gctttgagga 12060 ctaaacacaa aacaaacata atttgcaagg actgaaaaac aaaaaaataa ttttgcaagg 12120 acaaaaaaac aaaaaaaaaa aacaaaattg caaggaccaa aaatatattt aaaccaacat 12180 gaaattatgg tataaaacca ttcatatgtc ttcatctaat agcttaagct tttgggatag 12240 ttggttaaca atatggtatt agagtcttat gatttttagg tggtctttga gttcaatcct 12300 tgctgctccc agttctagtt aatttctttt tggtccactt caaataaaaa gttgaattta 12360 agggtaaggc agctggacct gcgcattaat catgtgtcag gctcaaaggg cttttgtatg 12420 gggggcatgt ttggaatata atatagaatc attcatgtgg tttcacctat caaggacaac 12480 tctagttttt gtcatacttg tattattaca gtgtctaaac tagacatgat ctttttccgg 12540 aaggaaattt aacttaaaag gaacttagat gcttcttgtt ctgtgatctt tatttgttta 12600 ttttttccaa tctttttaac aattgaaagg ttttagttgt atccaatctt tttatacatt 12660 tggactatct accatatcat ttagcaaact tgtttgctgc tcagattctc ctttggacta 12720 tctaccatat catttagcaa acctgttcac tgctcagatt ctcatttatt ctttgtttcc 12780 tctatttttc agtggcaagt tggagagtta aagagactga gaggatgata gcaatctgca 12840 cagaactcag aaaggtgagt gtcttgctaa ttcctttatg gtttcgatat tactggactt 12900 tttacatctc actgacctac tctgtcttgg tatttcagct aggagcaaca gttgaagaag 12960 gtcctgatta ctgtgtgatt actccacctg agaaattgaa tgtcacagct atagacacat 13020 atgatgacca cagaatggcc atggcattct ctcttgctgc ttgtggggat gttccagtaa 13080 ccatcaagga tcctggttgc accaggaaga catttccyga ctactttgaa gtccttgaga 13140 ggttmacaaa gcactaagca ttttgtacat tgagtaggaa gagagagaga gataaatact 13200 cacaaaacag tgagtatatg catggcttgc ttttgtttct taacattccc ttgtaagaac 13260 ttgagataat ttgtattgtt ggaaagagct attgattctg ttgtatcaaa gtaatttaat 13320 ttccagtaca gacttggctc tattcctcat atgtggtggt gtacattgca tctttgcatt 13380 tgatcccatt tctattggga taggaccata cctttttttg tttattattc aagtcaaact 13440 tagcagataa tatgtggtga ccagaaaata gtctagctag caaatagacc tgtgattgca 13500 tgtttgaatt caggacttca ggacatttaa ttaatgagtg acaatgttaa aaagctcgcc 13560 aacaggagtt gacacatctg attgagtctt ctattaacac taactgtaac ttgagtttga 13620 ttatcagatt cctcctgttg gtaggtaata tgtaaatttc actatatatt taccgaggtt 13680 ggtggtctta cttgactttg aagaggtgag tgtaatttaa acttttatat caaaaaaaga 13740 ttgctaaaag cttgagtggc atgcaacaaa tagcaatgaa agaatgacta tggccttggg 13800 aaccaaatgg ccacgtacca cttttccacc aacttgagag ccctggtcct ggatgatgcc 13860 cctttttttt tttcatttct ttgacaataa agaaagttct tattcttggc aattgcaagt 13920 cgtttgtgga agtcacatga aattcaccat aggcttcatt gttcaaatcc tttagtcact 13980 aactaaaggc tggacctatg caagaatttt ggctactctt ataaatgctg tgcggcaaag 14040 actacggaaa aatataaatt attgcatatc tagaggtgag gttcattgct cccatccatt 14100 tttccaagaa ctaaaatata tataaattat taatatgata ttacattgaa aaataatatt 14160 tttcttttaa atatgtgatc ataagtttaa ttttaagtct attcatacga aaaaaatatt 14220 tattagaaaa gattaattta ttaaatggat ctcaatattt taagaaatta acttttagct 14280 ctcaaccaac agatgatttg agttaaaaaa atgtatatat aaactattgc atatctgctg 14340 atttttgttt gtaacaccaa taagtgggca ttttactaaa tccatgtgac aatgtactga 14400 atgttttaga atacagtctg gtttgataat aaaacgtgca taaagtccag cttatgttaa 14460 ctcttaattc atggaaaatg atgatatgcg aattgaaaga aagaaaacca taatgtaagt 14520 gcagttttct ctctcttttt taatattatt caatatcaga ttgcacatgg gaaggggtat 14580 tggctcatgt gggatattag tttttgtccc ttacctaaaa agagagaaag agaaaaataa 14640 caatttaaaa agagtaccac cgctaccacc tttttcgctt ttaaattttt gttctgtttt 14700 cactactctt tcatgcgttg tttgttggct tctgatagtg acgaatatga tataatgatt 14760 ttatgttggg aaaaaagtgc catgtaaatt ctagagattg aaattttagc atcaaattat 14820 ttattttatc accttttaaa atttgttgca tgtgaaagaa tttgaagctc tccaacaagg 14880 aaataacact tcaatcctta gagtcatcct ctagatccca aaagaatgtg atgtttatac 14940 acattagtat atatatatat atatatatat atatatatat atatatatat atatatatat 15000 atatatatat agggtttata ttatattaat gagtgatgta cgaggacggt ggtgacacta 15060 tatggccaaa acaagtgtaa tataattatt tttttttctc aagtattact ctatccttga 15120 atattattag tcttaaatct tcaagcacct tgtgaacgaa gcaatcttgt cc 15172 37 522 DNA Figwort Mosaic Virus Enhancer 37 aagcttcccg ggccggccgc agctggcttg tggggaccag acaaaaaagg aatggtgcag 60 aattgttagg cgcacctacc aaaagcatct ttgcctttat tgcaaagata aagcagattc 120 ctctagtaca agtggggaac aaaataacgt ggaaaagagc tgtcctgaca gcccactcac 180 taatgcgtat gacgaacgca gtgacgacca caaaactcga gacttttcaa caaagggtaa 240 tatccggaaa cctcctcgga ttccattgcc cagctatctg tcactttatt gtgaagatag 300 tggaaaagga aggtggctcc tacaaatgcc atcattgcga taaaggaaag gccatcgttg 360 aagatgcctc tgccgacagt ggtcccaaag atggaccccc acccacgagg agcatcgtgg 420 aaaaagaaga cgttccaacc acgtcttcaa agcaagtgga ttgatgtgat atctccactg 480 acgtaaggga tgacgcacaa tcccactatc cttcttaatt aa 522 38 552 DNA Figwort Mosaic Virus Enhancer 38 aagcttcccg ggccggccgc agctggcttg tggggaccag acaaaaaagg aatggtgcag 60 aattgttagg cgcacctacc aaaagcatct ttgcctttat tgcaaagata aagcagattc 120 ctctagtaca agtggggaac aaaataacgt ggaaaagagc tgtcctgaca gcccactcac 180 taatgcgtat gacgaacgca gtgacgacca caaaactcga gaacatggtg gagcacgaca 240 cacttgtcta ctccaagaat atcaaagata cagtctcaga agaccagagg gctattgaga 300 cttttcaaca aagggtaata tcgggaaacc tcctcggatt ccattgccca gctatctgtc 360 acttcatcga aaggacagta gaaaaggaag atggcttcta caaatgccat cattgcgata 420 aaggaaaggc tatcgttcaa gatgcctcta ccgacagtgg tcccaaagat ggacccccac 480 ccacgaggaa catcgtggaa aaagaagacg ttccaaccac gtcttcaaag caagtggatt 540 gatgttaatt aa 552 39 28 DNA Artificial Sequence Primer 39 ctgcagggat cctggttgca ccaggaag 28 40 29 DNA Artificial Sequence Primer 40 gaattcccgg gtatggtgaa tttcatgtg 29 41 25 DNA Artificial Sequence Primer 41 gacttctcgg gtaccatcac attgc 25 42 55 DNA Artificial Sequence Primer 42 cacctgcagc aaccacagct gctgtcaaag aacgcattgc aataccagca tttcc 55 43 27 DNA Artificial Sequence Primer 43 aatttaatta attcataaat atgttac 27 44 73 DNA Artificial Sequence Primer 44 ggtcttctcc ttcttagttc tcaactactt gttcttctgc tgccagattt caattttcct 60 taaagttgtg aac 73 45 72 DNA Artificial Sequence Primer 45 atctggcagc agaagaacaa gtagttgaga actaagaagg agaagaccat ggcccaagtg 60 agcagagtgc ac 72 46 24 DNA Artificial Sequence Primer 46 ggcaatgtga tggatcccga gaag 24 47 27 DNA Artificial Sequence Primer 47 gcgccatggc ggcatcggtt tccaggg 27 48 33 DNA Artificial Sequence Primer 48 gcgggtacct cagacaagca cctgagctgc agc 33 49 25 DNA Artificial Sequence Primer 49 gcggcatgcc caacaatggc tcgtc 25 50 28 DNA Artificial Sequence Primer 50 gcggatcctt atttcttcag ttcagcca 28 51 9 PRT Motif MISC_FEATURE (5)..(5) Xaa is any amino acid but not S or T 51 Ala Leu Leu Met Xaa Ala Pro Leu Ala 1 5 52 8 PRT Motif MISC_FEATURE (5)..(5) Xaa is any amino acid but not V 52 Glu Ile Glu Ile Xaa Asp Lys Leu 1 5 53 7 PRT Motif MISC_FEATURE (3)..(3) Xaa is V or I 53 Phe Gly Xaa Xaa Xaa Glu His 1 5 54 7 PRT Motif MISC_FEATURE (3)..(3) Xaa is K orR 54 Ala Leu Xaa Xaa Leu Gly Leu 1 5 55 15 PRT Motif MISC_FEATURE (3)..(3) Xaa is any amino acid 55 Gly Leu Xaa Val Glu Xaa Asp Xaa Xaa Xaa Xaa Xaa Ala Xaa Val 1 5 10 15 56 9 PRT Motif MISC_FEATURE (5)..(5) Xaa is any amino acid but not K (and/or the amino acid at position 9 is any amino acid but not T) 56 Ile Thr Pro Pro Xaa Lys Xaa Xaa Xaa 1 5 57 8 PRT Motif MISC_FEATURE (3)..(3) Xaa is any amino acid but not N or L 57 Thr Ile Xaa Xaa Pro Gly Cys Thr 1 5 58 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is D or N 58 Xaa Tyr Phe Xaa Val Leu Xaa Xaa Xaa Xaa Xaa His 1 5 10 59 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 59 Xaa Val Glu Gly Cys Gly Gly Xaa Phe Pro Xaa Xaa 1 5 10 60 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 60 Xaa Val Val Gly Cys Gly Gly Xaa Phe Pro Xaa Glu 1 5 10 61 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 61 Xaa Val Val Gly Cys Gly Gly Xaa Phe Pro Xaa Xaa 1 5 10 62 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 62 Xaa Val Val Gly Cys Gly Gly Lys Phe Pro Xaa Xaa 1 5 10 63 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 63 Xaa Val Glu Gly Cys Gly Gly Lys Phe Pro Xaa Glu 1 5 10 64 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 64 Xaa Val Glu Gly Cys Gly Gly Xaa Phe Pro Xaa Glu 1 5 10 65 12 PRT Motif MISC_FEATURE (1)..(1) Xaa is I or V 65 Xaa Val Glu Gly Cys Gly Gly Lys Phe Pro Xaa Xaa 1 5 10 66 10 PRT Motif 66 Gly Asn Ala Gly Thr Ala Met Arg Pro Leu 1 5 10 67 10 PRT Motif 67 Gly Asn Ala Gly Ile Ala Met Arg Ser Leu 1 5 10 68 18 PRT Motif MISC_FEATURE (2)..(2) Xaa is A or V 68 Lys Xaa Ala Lys Arg Ala Val Val Val Gly Cys Gly Gly Lys Phe Pro 1 5 10 15 Val Glu 69 14 PRT Motif 69 Gly Asn Ala Gly Thr Ala Met Arg Pro Leu Thr Ala Ala Val 1 5 10 70 14 PRT Motif 70 Gly Asn Ala Gly Ile Ala Met Arg Ser Leu Thr Ala Ala Val 1 5 10 

1. A glyphosate resistant EPSPS enzyme wherein in comparison with the wild type EPSPS the protein sequence is modified in that a first position is mutated so that the residue at this position is lie rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPL in the wild type enzyme such that the modified sequence reads GNAGIAMRSL, wherein the enzyme does not comprise the sequence K(AN)AKRAVVVGCGGKFPVE, characterised in that the enzyme is stable and possesses at least one of the following sequence motifs (i) to (viii) in which X is any amino acid and Z, Z₁ and Z₂ are any amino acid other than those specified: (i) ALLMZAPLA, wherein Z is not S or T; (ii) EIEIZDKL, wherein Z is not V; (iii) FG(V/I)(K/S)ZEH, wherein Z is not V; (iv) AL(K/R)ZLGL, wherein Z is not R; (v) GLXVEZ₁DXZ₂XXXA(I/V)V, wherein Z₁ is not T and/or Z₂ is not E; (vi) ITPPZ₁K(LN)(K/N)Z₂, wherein Z, is not K and/or Z₂ is not T; (vii) TIZ(D/N)PGCT, wherein Z is not N or L; (viii) (D/N)YFXVLXZXX(K/R)H, wherein Z is not R.
 2. An enzyme according to claim 1, which comprises at least two of the motifs (i), (ii), (iii), (v) and (vi).
 3. An enzyme according to either of claims 1 or 2, wherein in motif (i) Z is A; in motif (ii) Z is I; in motif (iii) Z is A; in motif (iv) Z is K, T or A; in motif (v) Z₁ is R or A or less preferably D or E and Z₂ is preferably V or A or less preferably T; in sequence motif (vi) Z, is E or A and Z₂ is P, I or V; in motif (vii) Z is R or K; and in motif (viii) Z is T or S or less preferably Q.
 4. An enzyme according to claim 1, which comprises one or more sequences selected from the group consiting of:. (i) (I/V)VEGCGG(I/L/Q)FP(V/A/T)(S/G) (ii) (I/V)VVGCGG(I/L/Q)FP(V/A/T)E; (iii) (I/V)VVGCGG(I/L/Q)FP(V/A/T)(S/G); (iv) (I/V)VVGCGGKFP(V/A/T)(S/G); (v) (I/V)VEGCGGKFP(V/A/T)E; (vi) (I/V)VEGCGG(I/L/Q)FP(V/A/T)E; vii) (I/V)VEGCGGKFP(V/A/T)(S/G).


5. An isolated polynucleotide comprising a region which encodes an EPSPS according to any one of claims 1 to
 4. 6. A polynucleotide according to claim 5, having a sequence depicted in SEQ ID Nos. 4 or
 5. 7. A polynucleotide encoding an EPSPS, which polynucleotide is obtainable by screening plant genomic DNA libraries with a polynucleotide constituting an intron located within SEQ ID Nos. 4 or
 5. 8. A polynucleotide according to any one of claims 5-7, comprising the following components in the 5′ to 3′ direction of transcription: (i) At least one transcriptional enhancer being that enhancing region which is upstream from the transcriptional start of the sequence from which the enhancer is obtained and which enhancer per se does not function as a promoter either in the sequence in which it is endogenously comprised or when present heterologously as part of a construct; (ii) The promoter from the soybean EPSPS gene; (iii) The soybean genomic sequence which encodes the soybean EPSPS chloroplast transit peptide; (iv) The genomic sequence which encodes the soybean EPSPS; (v) A transcriptional terminator; wherein the soybean TPSPS coding sequence is modified in comparison with the wild type sequence in that a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPLTAAV in the wild type enzyme such that modified sequence reads GNAGIAMRSLTAAV.
 9. A polynucleotide according to claim 1, comprising the following components in the 5′ to 3′ direction of transcription: (i) At least one transcriptional enhancer being that enhancing region which is upstream from the transcriptional start of the sequence from which the enhancer is obtained and which enhancer per se does not function as a promoter either in the sequence in which it is endogenously comprised or when present heterologously as part of a construct; (ii) The promoter from the Brasicca napus EPSPS gene; (iii) The Brasicca napus genomic sequence which encodes the Brasicca napus EPSPS chloroplast transit peptide; (iv) The genomic sequence which encodes the Brasicca napus EPSPS; (v) A transcriptional terminator; wherein the Brasicca napus EPSPS coding sequence is modified in comparison with the wild type sequence, in that a first position is mutated so that the residue at this position is Ile rather than Thr and a second position is mutated so that the residue at this position is Ser rather than Pro, the mutations being introduced into EPSPS sequences which comprise the conserved region GNAGTAMRPLTAAV in the wild type enzyme such that modified sequence reads GNAGIAMRSLTAAV.
 10. A polynucleotide according to any one of claims 5-9, further comprising a sequence which encodes a chloroplast transit peptide/phosphoenolpyruvate synthase (CTP/PPS) or a chloroplast transit peptide/pyruvate orthophosphate di-kinase (CTP/PPDK), which sequence is under expression control of a plant operable promoter.
 11. A polynucleotide according to the preceding claim, wherein the CTP and PPDK encoding sequences are non-heterologous with respect to each other.
 12. A polynucleotide according to any one of claims 5-11, wherein the said enhancing region constitutes a sequence, the 3′ end of which is at least 40 nucleotides upstream of the closest transcriptional start of the sequence from which the enhancer is obtained.
 13. A polynucleotide according to claim 12, wherein the enhancing region constitutes a region the 3′ end of which is at least 60 nucleotides upstream of the said closest start.
 14. A polynucleotide according to claim 12, wherein the said enhancing region constitutes a sequence the 3′ end of which is at least 10 nucleotides upstream from the first nucleotide of the TATA consensus of the sequence from which the enhancer is obtained.
 15. A polynucleotide according to any one of claims 5-14, comprising first and second transcriptional enhancers which are tandemly present in the polynucleotide.
 16. A polynucleotide according to any one of claims 5-15, wherein the 3′ end of the enhancer, or first enhancer, is between about 100 to about 1000 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 17. A polynucleotide according to any one of claims 5-16, wherein the 3′ end of the enhancer, or first enhancer, is between about 150 to about 1000 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 18. A polynucleotide according to any one of claims 5-17, wherein the 3′ end of the enhancer, or first enhancer, is between about 300 to about 950 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 19. A polynucleotide according to any one of claims 5-18, wherein the 3′ end of the enhancer, or first enhancer, is between about 770 and about 790 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 20. A polynucleotide according to any one of claims 5-19, wherein the 3′ end of the enhancer, or first enhancer, is between about 300 and about 380 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 21. A polynucleotide according to any one of claims 5-18 and 20, wherein the 3′ end of the enhancer, or first enhancer, is between about 320 and about 350 nucleotides upstream of the codon corresponding to the translational start of the EPSPS transit peptide, or the first nucleotide of an intron in the 5′ untranslated region.
 22. A polynucleotide according to any one of claims 5-21, wherein the region upstream of the promoter from the EPSPS gene comprises at least one enhancer derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters.
 23. A polynucleotide according to any one of claims 5-21, wherein the region upstream of the promoter from the EPSPS coding sequence comprises at least one enhancer derived from a sequence which is upstream from the transcriptional start of a promoter selected from the group consisting of those of the actin, rolDFd, S-adenosyl homocysteinase, histone, tubulin, polyubiquitin and plastocyasnin genes and the CaMV35S and FMV35S genes.
 24. A polynucleotide according to claim 23, comprising in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of an actin gene.
 25. A polynucleotide according to claim 23, comprising in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the rolDfd gene.
 26. A polynucleotide according to claim 23, comprising in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of a histone gene.
 27. A polynucleotide according to claim 23, comprising in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of either the CaMV35S or FMV35S promoters, and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of a tubulin gene.
 28. A polynucleotide according to claim 23, comprising in the 5′ to 3′ direction a first enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the FMV 35S promoter and a second enhancer comprising a transcriptional enhancing region derived from a sequence which is upstream from the transcriptional start of the CaMV35S promoter.
 29. A polynucleotide according to any one of claims 5-28, wherein the nucleotides 5′ of the codon which constitutes the translational start of the soybean EPSPS chloroplast transit peptide are Kozack preferred.
 30. A polynucleotide according to any one of claims 8 to 29, wherein 5′ of the genomic sequence which encodes the EPSPS CTP there is located a 5′ untranslated leader sequence derived from a relatively highly expressed gene
 31. A polynucleotide according to the preceding claim, wherein the said highly expressed gene is selected from the group consisting of those which encode glucanase, chalcone synthase and Rubisco.
 32. A polynucleotide according to any one of claims 8-31, which comprises a virally derived translational enhancer or non-viral translational enhancer located within the non translated region 5′ of the genomic sequence which encodes the EPSPS chloroplast transit peptide.
 33. A polynucleotide according to any one of claims 5-32, further comprising regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, dessication, and herbicides.
 34. A polynucleotide according to claim 33, wherein the herbicide is other than glyphosate.
 35. A polynucleotide according to the preceding claim wherein the herbicide is a protoporphyrinogen oxidase (PPGO) inhibitor, in particular butefenicil, and the corresponding resistance protein is a PPGO or inhibitor resistant variant thereof.
 36. A polynucleotide according to either of claims 33 to 35, wherein the insect resistance conferring regions encode crystal toxins derived from Bt, including secreted Bt toxins; protease inhibitors, lectins, Xenhorabdus/Photorhabdus toxins; the fungus resistance conferring regions are selected from the group consisting of those encoding known AFPs, defensins, chitinases, glucanases, Avr-Cf9; the bacterial resistance conferring regions are selected from the group consisting of those encoding cecropins and techyplesin and analogues thereof; the virus resistance regions are selected from the group consisting of genes encoding virus coat proteins, movement proteins, viral replicases, and antisense and ribozyme sequences which are known to provide for virus resistance; the stress, salt, and drought resistance conferring regions are selected from those that encode Glutathione-S-transferase and peroxidase, the sequence which constitutes the known CBF1 regulatory sequence and genes which are known to provide for accumulation of trehalose.
 37. A polynucleotide according to claim 36, wherein the insect resistance conferring regions are selected from the group consisting of those that encode crylAc, crylAb, cry3A, cry1BC, Vip1A, Vip1B, Vip3A, Vip3B, cystein protease inhibitor, and snowdrop lectin.
 38. A polynucleotide according to any preceding claim, which is modified in that mRNA instability motifs and/or unwanted splice regions are removed, or crop preferred codons are used so that expression of the thus modified polynucleotide in a plant yields substantially similar protein having a substantially similar activity/function to that obtained by expression of the protein encoding regions of the unmodified polynucleotide in the organism in which they are endogenous.
 39. A polynucleotide according to the preceding claim, wherein the degree of identity between the modified polynucleotide and a polynucleotide endogenously contained within the said plant and encoding substantially the same protein is such as to prevent co-suppression between the modified and endogenous sequences.
 40. A polynucleotide according to the preceding claim, wherein the said degree is less than about 70%.
 41. A vector comprising the polynucleotide of any preceding claim.
 42. Plant material which has been transformed with the polynucleotide of any one of claims 5-40, or the vector of claim
 41. 43. Plant material which has been transformed with the polynucleotide of any one of claims 5-40 or the vector of claim 41, and which has been, or is, further transformed with a polynucleotide comprising regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, desiccation, and herbicides.
 44. Morphologically normal, fertile whole plants which have been regenerated from the material according to either of claims 42 or 43, their progeny seeds and parts.
 45. Morphologically normal fertile whole plants which result from the crossing of pints which have been regenerated from material which has been transformed with the polynucleotide of any one of claims 5-40 and plants which result from regeneration of material transformed with a polyncleotide which comprises a sequence which encodes a protein capable of providing for elevated levels of phosphoenolpyruvate in the chloroplast.
 46. Plants according to the preceding claim, wherein the said capable protein is a fusion of a CTP and PPS or a fusion of a CTP and a PPDK.
 47. Morphologically normal fertile whole plants which comprise the polynucleotide of any one of claims 5-40 and which result from the crossing of plants which have been regenerated from material transformed with the polynucleotide of any one of claims 5-40 or the vector of claim 41, and plants which have been transformed with a polynucleotide comprising regions encoding a CTP/PPS or CTPPPDK, and/or regions encoding proteins capable of conferring upon plant material containing it at least one of the following agronomically desirable traits: resistance to insects, fungi, viruses, bacteria, nematodes, stress, desiccation, and herbicides, the progeny of the resultant plants, their seeds and parts.
 48. Plants according to any one of claims 44 to 47, selected from the group consisting of field crops, fruits and vegetables such as canola, sunflower, tobacco, sugar beet, cotton, maize, wheat, barley, rice, sorghum, tomato, mango, peach, apple, mangel worzel, pear, strawberry, banana, melon, potato, carrot, lettuce, cabbage, onion, soya spp, sugar cane, pea, field beans, poplar, grape, citrus, alfalfa, rye, oats, turf and forage grasses, flax and oilseed rape, and nut producing plants insofar as they are not already specifically mentioned, their progeny, seeds and parts.
 49. Soybean, canola, brassica, cotton, sugar beet, sunflower, peas, potatoes and mangel worzels according to any one of claims 44-48.
 50. A method of selectively controlling weeds in a field, the field comprising weeds and plants or progeny according to any one of claims 44-49, the method comprising application to the field of a glyphosate type herbicide in an amount sufficient to control the weeds without substantially affecting the plants.
 51. A method according to the preceding claim, further comprising application to the field either before or after application of the glyphosate herbicide of one or more of the following: a herbicide, insecticide, fungicide, nematicide, bacteriocide and an anti-viral.
 52. A method of producing plants which are substantially tolerant or substantially resistant to glyphosate herbicide, comprising the steps of: (i) transforming plant material with the polynucleotide of any one of claims 5 to 40 or the vector of claim 41; (ii) selecting the thus transformed material; and (iii) regenerating the thus selected material into morphologically normal fertile whole plants.
 53. A method according to the preceding claim, wherein the transformation involves the introduction of the polynucleotide into the material by: (i) biolistic bombardment of the material with particles coated with the polynucleotide; or (ii) impalement of the material on silicon carbide fibres which are coated with a solution comprising the polynucleotide; or (iii) introduction of the polynucleotide or vector into Agrobacterium and co-cultivation of the thus transformed Agiobacterium with plant material which is thereby transformed and is subsequently regenerated.
 54. A method according to the preceding claim, wherein the transformed material is selected by its resistance to glyphosate.
 55. Use of the polynucleotide of any one of claims 5 to 40, or the vector of claim 41, in the production of plant tissues and/or morphologically normal fertile whole plants which are substantially tolerant or substantially resistant to glyphosate herbicide.
 56. Use of the polynucleotide of any one of claims 5 to 40, or the vector of claim 41, in the production of a herbicidal target for the high throughput in vitro screening of potential herbicides.
 57. A method of selecting biological material transformed so as to express a gene of interest, wherein the transformed material comprises the polynucleotide of any one of claims 5 to 40 or the vector of claim 41 and wherein the selection comprises exposing the transformed material to glyphosate or a salt thereof, and selecting surviving material.
 58. A method according to the preceding claim, wherein the biological material is of plant origin.
 59. A method according to the preceding claim, wherein the plant is a dicot.
 60. A method according to'the preceding claim, wherein the dicot is selected from group consisting of soybean, cotton, sugar beet, Brassica napus, campestris or oleraceae.
 61. A method for regenerating a fertile transformed plant to contain foreign DNA comprising the steps of: (a) producing regenerable tissue from said plant to be transformed; (b) transforming said regenerable tissue with said foreign DNA, wherein said foreign DNA comprises a selectable DNA sequence, wherein said sequence functions in a regenerable tissue as a selection device; (c) between about one day to about 60 days after step (b), placing said regenerable tissue from step (b) in a medium capable of producing shoots from said tissue, wherein said medium may further contain a compound used to select regenerable tissue containing said selectable DNA sequence to allow identification or selection of the transformed regenerated tissue; (d) after at least one shoot has formed from the selected tissue of step (c) transferring said shoot to a second medium capable of producing roots from said shoot to produce a plantlet, wherein the second medium optionally contains the said compound; and (e) growing said plantlet into a fertile transgenic plant wherein the foreign DNA is transmitted to progeny plants in Mendelian fashion, wherein between step (b) and step (c) there is an optional step of placing the transformed material onto callus inducing medium, characterised in that the foreign DNA is, or the selectable DNA sequence comprised by the foreign DNA comprises, the polynucleotide according to any one of claims 5 to 40, and the said compound is glyphosate or a salt thereof.
 62. A method according to the preceding claim, wherein the plant is a dicot selected from the group consisting soybean, cotton, sugar beet, Brassica napus, catizpestiris or oleraceae.
 63. A method according to either of claims 61 or 62, wherein the said regenerable tissue is selected from the group consisting of embryogenic calli, somatic embryos, immature embryos etc.
 64. A diagnostic kit comprising means for detecting the enzyme of any one of claims 1-4 or that encoded by the polynucleotide of any one of claims 5 to 40 or the polynucleotide or vector of any one of claims 5 to
 41. 